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The Latest Software Design and Architecture Topics

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Eclipse Project Explorer Filters
Wondering why the Eclipse Project view might not show all files in the Project Explorer view? For example it shows this: Eclipse Project Explorer View But on disk I have more files? Where are they? :idea: I’m using Eclipse Luna (4.4) in this post, but things are very similar for earlier versions of Eclipse. File System has more Files? Checking the files on my file system (e.g. with the Windows Explorer), I have more files/folders listed: Files on the File System Obviously, files and folders starting with a dot (‘.’) are not shown in the Project Explorer view. Project View Filters The reason is that the Eclipse Project Explorer view has a filter built-in to hide files. There is a setting for this in the View Menu of that view: Project Explorer View Menu There is a ‘Customize View…‘ menu item: Customize Project Explorer View And here I have the filters: Customize Project Explorer View Now it should be clear why the files starting with a dot are ont shown: they are filtered out with the filter for “.*”: Project Explorer View Filters Un-checking that filter will show now as well the dot files: Showing Dot Files in Project Explorer View Defining my own Filters The list of filters in the project view is provided by the plugins. And unfortunately there is no way to define my own filters in the above dialog, unless I would implement my Java plugin. Defining my own filters without programming things is possible, it is just in a different place:-). For example I do not want to see that ‘ProjectInfo.xml’. For this, I select the project and use the ‘Properties’ menu. Inside the project properties, there is Resource > Resource Filters: Resource Filters Use the Add button to add a new filter: Adding Filter To exclude just the ProjectInfo.xml: Exclude all (this will exclude all files matching my filter) Applies to Files (I only want to have it applied to files) [Name] [matches] the file name Excluding Files With that, I can build any kind of filters. Pressing OK, and it gets added to my filter list: Added Filter Now the ProjectInfo.xml is not listed any more in the Project Explorer view: Filtered ProjectView.xml Summary The Eclipse Project Explorer view has a setting to turn on/off filters for files/folders, or in general to configure the view. I can use project resource filters to define my own filters too. Happy Filtering :-)
May 22, 2015
by Erich Styger
· 8,087 Views · 3 Likes
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Efficient Cassandra Write Pattern for Micro-Batching
The best way to write to a Cassandra cluster are concurrent asynchronous writes. In cases where data exhibits strong temporal locality, speed can be improved.
May 20, 2015
by John Georgiadis
· 35,074 Views · 1 Like
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Why Android Studio Is Better For Android Developers Instead Of Eclipse
Besides, Android Studio platform developers also use Eclipse to develop applications, but always thought of Eclipse like a "Student-Project IDE " and learned about it.
May 20, 2015
by Mehul Rajput
· 68,391 Views · 1 Like
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How To Set Up a Tomcat, Apache and mod_jk Cluster
In this article I will go through a common set-up for a small production environment. A single tier, load balanced application server cluster. Overview A high level overview of what we will be doing. Downloading and installing Apache HTTP server and mod_jk Downloading Tomcat Downloading Java Configuring two local Tomcat servers Clustering the two Tomcat servers Configuring Apache to use mod_jk to forward request to Tomcat Deploying application to Tomcat server that tests our set-up Introduction What is Apache? Apache is an HTTP server. What is mod_jk? It is an Apache module that allows AJP communication between Apache and a back end application server like Tomcat.I am running this on Ubuntu 14.04LTS installed on a dual boot PC with Windows 7. Download Apache2 We are going to use Ubuntu's APT package maintenance system to obtain and install Apache2. sudo apt-get install apache2 This will install in /etc/apache2 Download and install mod_jk The mod_jk module is not included in the Apache2 download so must be obtained and installed separately. The installation requires that the mod_jk module is visible to Apache and configured to ensure that Apache knows where to look for it and what to do with the requests you want to proxy. sudo apt-get install libapache2-mod-jk This will install in /etc/libapache2-mod-jk also two files have been added to the /etc/apache2/mods-available folder. Downloading and installing Tomcat 8 At the time of writing this Tomcat 8 does not have a package in APT so you must download the binaries from the tomcat website.http://tomcat.apache.org/download-80.cgi select the appropriate binary distribution and extract it as follows. tar xvzf apache-tomcat-8.0.5.tar.gz We need two copies of the Tomcat server to be load balanced. I created two directories in the /opt/ location: /opt/tomcat-server1/ and /opt/tomcat-server2/ and copied tomcat into each one. Download and install Java Download Java from APT as follows: apt-get install openjdk-7-jdk and set JAVA_HOME in .bashrc vim ~/.bashrc export JAVA_HOME=/usr/lib/jvm/java-7-openjdk-amd64 Configure two local Tomcat servers We will edit only the server.xml of the server2 installation of tomcat. We need to change port numbers to avoid conflicts.We change the following: and comment out the HTTP Connector as we only want the web application to be accessible through the load balancer.Here is my server2 Tomcat server.xml configuration. Configure mod_jk Load balancing is configured in the workers.properties file, located /etc/libapache2-mod-jk/ where workers represent actual or virtual workers.We will define two actual workers and two virtual workers which map to the Tomcat servers. In the worker.list property I have defined two virtual workers: status and loadbalancer, I will refer to these later in the Apache configuration.Workers for each server have been defined using values for the server.xml configuration files. I used the port values for the AJP connectors and I have included an lbfactor that sets the preference that the load balancer will show for that server.Finally we define the virtual workers. The loadbalancer worker is set to type lb and set the workers that represent the Tomcat servers in the balancer_workers properties. The status only needs to be set to type status. worker.list=loadbalancer,status worker.server1.port=8009worker.server1.host=localhostworker.server1.type=ajp13 worker.server2.port=9009worker.server2.host=localhostworker.server2.type=ajp13 worker.server1.lbfactor=1worker.server2.lbfactor=1 worker.loadbalancer.type=lbworker.loadbalancer.balance_workers=server1,server2 worker.status.type=status Ensure that you remove any other worker configuration that are not being used. Configure Apache Web Server to forward requests You will need to add the following to the Apache configurations located in etc/apache2/sites-enabled/000-default.conf JkMount /status status JkMount /* loadbalancer Verify the installation To test that all has been configured correctly we need to deploy an application. A sample application that has been used for years to test such configurations is called the ClusterJSP sample application. You can find it by googling in or from the JBoss site.Now deploy the war to the webapps folder on both servers and start each server using the start-up script /opt/tomcat-server1/bin/startup.sh.Go to http://localhost/clusterjsp/HaJsp.jsp and you should see the page show HttpSession information. Now lets look at the mod_jk status page: http://localhost/status. You will see that this page shows information about the load balancer workers and the workers it is balancing. If everything is working you will see the worker error state show OK or OK/IDLE if they are not currently balancing load. Things to try out Enable sticky sessions: Configure jvmRoute in the server.xml configuration. Further reading Loadbalancing with mod_jk and ApacheWorking with mod_jk Connecting Apache's Web Server to Multiple Instances of Tomcat
May 19, 2015
by Alex Theedom
· 10,827 Views · 1 Like
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Integrating External APIs into your Meteor.js Application
Meteor itself does not rely on REST APIs, but it can easily access data from other services. This article is an excerpt from the book Meteor in Action and explains how you can integrate third-party data into your applications by accessing RESTful URLs from the server-side. Many applications rely on external APIs to retrieve data. Getting information regarding your friends from Facebook, looking up the current weather in your area, or simply retrieving an avatar image from another website – there are endless uses for integrating additional data. They all share a common challenge: APIs must be called from the server, but an API usually takes longer than executing the method itself. You need to ensure that the result gets back to the client – even if it takes a couple of seconds. Let’s talk about how to integrate an external API via HTTP. Based on the IP address of a visitor, you can tell various information about their current location, e.g., coordinates, city or timezone. There is a simple API that takes an IPv4 address and returns all these tidbits as a JSON object. The API is called Telize. Making RESTful calls with the http package In order to communicate with RESTful external APIs such as Telize, you need to add the http package: meteor add http While the http package allows you to make HTTP calls from both client and server, the API call in this example will be performed from the server only. Many APIs require you to provide an ID as well as a secret key to identify the application that makes an API request. In those cases you should always run your requests from the server. That way you never have to share secret keys with clients. Let's look at a graphic to explain the basic concept. A user requests location information for an IP address (step 1). The client application calls a server method called geoJsonforIp (step 2) that makes an (asynchronous) call to the external API using the HTTP.get() method (step 3). The response (step 4) is a JSON object with information regarding the geographic location associated with an IP address, which gets sent back to the client via a callback (step 5). Using a synchronous method to query an API Let’s add a method that queries telize.com for a given IP address as shown in the following listing. This includes only the bare essentials for querying an API for now. Remember: This code belongs in a server-side only file or inside a if (Meteor.isServer) {} block. Meteor.methods({ // The method expects a valid IPv4 address 'geoJsonForIp': function (ip) { console.log('Method.geoJsonForIp for', ip); // Construct the API URL var apiUrl = 'http://www.telize.com/geoip/' + ip; // query the API var response = HTTP.get(apiUrl).data; return response; } }); Once the method is available on the server, querying the location of an IP works simply by calling the method with a callback from the client: Meteor.call('geoJsonForIp', '8.8.8.8', function(err,res){ console.log(res); }); While this solution appears to be working fine there are two major flaws to this approach: If the API is slow to respond requests will start queuing up. Should the API return an error there is no way to return it back to the UI. To address the issue of queuing, you can add an unblock() statement to the method: this.unblock(); Calling an external API should always be done asynchronously. That way you can also return possible error values back to the browser, which will solve the second issue. Let’s create a dedicated function for calling the API asynchronously to keep the method itself clean. Using an asynchronous method to call an API The listing below shows how to issue an HTTP.get call and return the result via a callback. It also includes error handling that can be shown on the client. var apiCall = function (apiUrl, callback) { // try…catch allows you to handle errors try { var response = HTTP.get(apiUrl).data; // A successful API call returns no error // but the contents from the JSON response callback(null, response); } catch (error) { // If the API responded with an error message and a payload if (error.response) { var errorCode = error.response.data.code; var errorMessage = error.response.data.message; // Otherwise use a generic error message } else { var errorCode = 500; var errorMessage = 'Cannot access the API'; } // Create an Error object and return it via callback var myError = new Meteor.Error(errorCode, errorMessage); callback(myError, null); } } Inside a try…catch block, you can differentiate between a successful API call (the try block) and an error case (the catch block). A successful call may return null for the error object of the callback, an error will return only an error object and null for the actual response. There are different types of errors and you want to differentiate between a problem with accessing the API and an API call that got an error inside the returned response. This is what the if statement checks for – in case the error object has a response property both code and message for the error should be taken from it; otherwise you can display a generic error 500 that the API could not be accessed. Each case, success and failure, returns a callback that can be passed back to the UI. In order to make the API call asynchronous you need to update the method as shown in the next code snippet. The improved code unblocks the method and wraps the API call in a wrapAsync function. Meteor.methods({ 'geoJsonForIp': function (ip) { // avoid blocking other method calls from the same client this.unblock(); var apiUrl = 'http://www.telize.com/geoip/' + ip; // asynchronous call to the dedicated API calling function var response = Meteor.wrapAsync(apiCall)(apiUrl); return response; } }); Finally, to allow requests from the browser and show error messages you should add a template similar to the following code. Query the location data for an IP Look up location {{#with location} {{#if error} There was an error: {{error.errorType} {{error.message}! {{else} The IP address {{location.ip} is in {{location.city} ({{location.country}). {{/if} {{/with} A Session variable called location is used to store the results from the API call. Clicking the button takes the content of the input box and sends it as a parameter to the geoJsonForIp method. The Session variable is set to the value of the callback. This is the required JavaScript code for connecting the template with the method call: Template.telize.helpers({ location: function () { return Session.get('location'); } }); Template.telize.events({ 'click button': function (evt, tpl) { var ip = tpl.find('input#ipv4').value; Meteor.call('geoJsonForIp', ip, function (err, res) { // The method call sets the Session variable to the callback value if (err) { Session.set('location', {error: err}); } else { Session.set('location', res); return res; } }); } }); As a result you will be able to make API calls from the browser just like in this figure: And that’show to integrate an external API via HTTP!
May 15, 2015
by Stephan Hochhaus
· 40,175 Views
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Log Collection With Graylog on AWS
Log collection is essential to properly analyzing issues in production. An interface to search and be notified about exceptions on all your servers is a must. Well, if you have one server, you can easily ssh to it and check the logs, of course, but for larger deployments, collecting logs centrally is way more preferable than logging to 10 machines in order to find “what happened”. There are many options to do that, roughly separated in two groups – 3rd party services and software to be installed by you. 3rd party (or “cloud-based” if you want) log collection services include Splunk,Loggly, Papertrail, Sumologic. They are very easy to setup and you pay for what you use. Basically, you send each message (e.g. via a custom logback appender) to a provider’s endpoint, and then use the dashboard to analyze the data. In many cases that would be the preferred way to go. In other cases, however, company policy may frown upon using 3rd party services to store company-specific data, or additional costs may be undesired. In these cases extra effort needs to be put into installing and managing an internal log collection software. They work in a similar way, but implementation details may differ (e.g. instead of sending messages with an appender to a target endpoint, the software, using some sort of an agent, collects local logs and aggregates them). Open-source options include Graylog, FluentD, Flume, Logstash. After a very quick research, I considered graylog to fit our needs best, so below is a description of the installation procedure on AWS (though the first part applies regardless of the infrastructure). The first thing to look at are the ready-to-use images provided by graylog, including docker, openstack, vagrant and AWS. Unfortunately, the AWS version has two drawbacks – it’s using Ubuntu, rather than the Amazon AMI. That’s not a huge issue, although some generic scripts you use in your stack may have to be rewritten. The other was the dealbreaker – when you start it, it doesn’t run a web interface, although it claims it should. Only mongodb, elasticsearch and graylog-server are started. Having 2 instances – one web, and one for the rest would complicate things, so I opted for manual installation. Graylog has two components – the server, which handles the input, indexing and searching, and the web interface, which is a nice UI that communicates with the server. The web interface uses mongodb for metadata, and the server uses elasticsearch to store the incoming logs. Below is a bash script (CentOS) that handles the installation. Note that there is no “sudo”, because initialization scripts are executed as root on AWS. #!/bin/bash # install pwgen for password-generation yum upgrade ca-certificates --enablerepo=epel yum --enablerepo=epel -y install pwgen # mongodb cat >/etc/yum.repos.d/mongodb-org.repo <<'EOT' [mongodb-org] name=MongoDB Repository baseurl=http://downloads-distro.mongodb.org/repo/redhat/os/x86_64/ gpgcheck=0 enabled=1 EOT yum -y install mongodb-org chkconfig mongod on service mongod start # elasticsearch rpm --import https://packages.elasticsearch.org/GPG-KEY-elasticsearch cat >/etc/yum.repos.d/elasticsearch.repo <<'EOT' [elasticsearch-1.4] name=Elasticsearch repository for 1.4.x packages baseurl=http://packages.elasticsearch.org/elasticsearch/1.4/centos gpgcheck=1 gpgkey=http://packages.elasticsearch.org/GPG-KEY-elasticsearch enabled=1 EOT yum -y install elasticsearch chkconfig --add elasticsearch # configure elasticsearch sed -i -- 's/#cluster.name: elasticsearch/cluster.name: graylog2/g' /etc/elasticsearch/elasticsearch.yml sed -i -- 's/#network.bind_host: localhost/network.bind_host: localhost/g' /etc/elasticsearch/elasticsearch.yml service elasticsearch stop service elasticsearch start # java yum -y update yum -y install java-1.7.0-openjdk update-alternatives --set java /usr/lib/jvm/jre-1.7.0-openjdk.x86_64/bin/java # graylog wget https://packages.graylog2.org/releases/graylog2-server/graylog-1.0.1.tgz tar xvzf graylog-1.0.1.tgz -C /opt/ mv /opt/graylog-1.0.1/ /opt/graylog/ cp /opt/graylog/bin/graylogctl /etc/init.d/graylog sed -i -e 's/GRAYLOG2_SERVER_JAR=\${GRAYLOG2_SERVER_JAR:=graylog.jar}/GRAYLOG2_SERVER_JAR=\${GRAYLOG2_SERVER_JAR:=\/opt\/graylog\/graylog.jar}/' /etc/init.d/graylog sed -i -e 's/LOG_FILE=\${LOG_FILE:=log\/graylog-server.log}/LOG_FILE=\${LOG_FILE:=\/var\/log\/graylog-server.log}/' /etc/init.d/graylog cat >/etc/init.d/graylog <<'EOT' #!/bin/bash # chkconfig: 345 90 60 # description: graylog control sh /opt/graylog/bin/graylogctl $1 EOT chkconfig --add graylog chkconfig graylog on chmod +x /etc/init.d/graylog # graylog web wget https://packages.graylog2.org/releases/graylog2-web-interface/graylog-web-interface-1.0.1.tgz tar xvzf graylog-web-interface-1.0.1.tgz -C /opt/ mv /opt/graylog-web-interface-1.0.1/ /opt/graylog-web/ cat >/etc/init.d/graylog-web <<'EOT' #!/bin/bash # chkconfig: 345 91 61 # description: graylog web interface sh /opt/graylog-web/bin/graylog-web-interface > /dev/null 2>&1 & EOT chkconfig --add graylog-web chkconfig graylog-web on chmod +x /etc/init.d/graylog-web #configure mkdir --parents /etc/graylog/server/ cp /opt/graylog/graylog.conf.example /etc/graylog/server/server.conf sed -i -e 's/password_secret =.*/password_secret = '$(pwgen -s 96 1)'/' /etc/graylog/server/server.conf sed -i -e 's/root_password_sha2 =.*/root_password_sha2 = '$(echo -n password | shasum -a 256 | awk '{print $1}')'/' /etc/graylog/server/server.conf sed -i -e 's/application.secret=""/application.secret="'$(pwgen -s 96 1)'"/g' /opt/graylog-web/conf/graylog-web-interface.conf sed -i -e 's/graylog2-server.uris=""/graylog2-server.uris="http:\/\/127.0.0.1:12900\/"/g' /opt/graylog-web/conf/graylog-web-interface.conf service graylog start sleep 30 service graylog-web start You may also want to set a TTL (auto-expiration) for messages, so that you don’t store old logs forever. Here’s how # wait for the index to be created INDEXES=$(curl --silent "http://localhost:9200/_cat/indices") until [[ "$INDEXES" =~ "graylog2_0" ]]; do sleep 5 echo "Index not yet created. Indexes: $INDEXES" INDEXES=$(curl --silent "http://localhost:9200/_cat/indices") done # set each indexed message auto-expiration (ttl) curl -XPUT "http://localhost:9200/graylog2_0/message/_mapping" -d'{"message": {"_ttl" : { "enabled" : true, "default" : "15d" }}' Now you have everything running on the instance. Then you have to do some AWS-specific things (if using CloudFormation, that would include a pile of JSON). Here’s the list: you can either have an auto-scaling group with one instance, or a single instance. I prefer the ASG, though the other one is a bit simpler. The ASG gives you auto-respawn if the instance dies. set the above script to be invoked in the UserData of the launch configuration of the instance/asg (e.g. by getting it from s3 first) allow UDP port 12201 (the default logging port). That should happen for the instance/asg security group (inbound), for the application nodes security group (outbound), and also as a network ACL of your VPC. Test the UDP connection to make sure it really goes through. Keep the access restricted for all sources, except for your instances. you need to pass the private IP address of your graylog server instance to all the application nodes. That’s tricky on AWS, as private IP addresses change. That’s why you need something stable. You can’t use an ELB (load balancer), because it doesn’t support UDP. There are two options: Associate an Elastic IP with the node on startup. Pass that IP to the application nodes. But there’s a catch – if they connect to the elastic IP, that would go via NAT (if you have such), and you may have to open your instance “to the world”. So, you must turn the elastic IP into its corresponding public DNS. The DNS then will be resolved to the private IP. You can do that by manually and hacky: 1 GRAYLOG_ADDRESS="ec2-$GRAYLOG_ADDRESS//./-}.us-west-1.compute.amazonaws.com" or you can use the AWS EC2 CLI to obtain the instance details of the instance that the elastic IP is associated with, and then with another call obtain its Public DNS. Instead of using an Elastic IP, which limits you to a single instance, you can use Route53 (the AWS DNS manager). That way, when a graylog server instance starts, it can append itself to a route53 record, that way allowing for a round-robin DNS of multiple graylog instances that are in a cluster. Manipulating the Route53 records is again done via the AWS CLI. Then you just pass the domain name to applications nodes, so that they can send messages. alternatively, you can install graylog-server on all the nodes (as an agent), and point them to an elasticsearch cluster. But that’s more complicated and probably not the intended way to do it configure your logging framework to send messages to graylog. There are standard GELF (the greylog format) appenders, e.g. this one, and the only thing you have to do is use the Public DNS environment variable in the logback.xml (which supports environment variable resolution). You should make the web interface accessible outside the network, so you can use an ELB for that, or the round-robin DNS mentioned above. Just make sure the security rules are tight and not allowing external tampering with your log data. If you are not running a graylog cluster (which I won’t cover), then the single instance can potentially fail. That isn’t a great loss, as log messages can be obtained from the instances, and they are short-lived anyway. But the metadata of the web interface is important – dashboards, alerts, etc. So it’s good to do regular backups (e.g. with mongodump). Using an EBS volume is also an option. Even though you send your log messages to the centralized log collector, it’s a good idea to also keep local logs, with the proper log rotation and cleanup. It’s not a trivial process, but it’s essential to have log collection, so I hope the guide has been helpful.
May 14, 2015
by Bozhidar Bozhanov
· 20,010 Views
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Docker Machine on Windows - How To Setup You Hosts
I've been playing around with Docker a lot lately. Many reasons for that, one for sure is, that I love to play around with latest technology and even help out to build a demo or two or a lab. The main difference, between what everybody else of my coworkers is doing is, that I run my setup on Windows. Like most of the middleware developers out there. So, If you followed Arun's blog about "Docker Machine to Setup Docker Host" you might have tried to make this work on windows already. Here is the ultimate short how-to guide on using Docker Machine to administrate and spin up your Docker hosts. Docker Machine Machine lets you create Docker hosts on your computer, on cloud providers, and inside your own data center. It creates servers, installs Docker on them, then configures the Docker client to talk to them. You basically don't have to have anything installed on your machine prior to this. Which is a hell lot easier, than having to manually install boot2docker before. So, let's try this out. You want to have at least one thing in place before starting with anything Docker or Machine. Go and get Git for Windows (aka msysgit). It has all kinds of helpful unix tools in his belly, which you need anyway. Prerequisites - The One For All Solution The first is to install the windows boot2docker distribution which I showed in an earlier blog. It contains the following bits configured and ready for you to use: - VirtualBox - Docker Windows Client Prerequisites- The Bits And Pieces I dislike the boot2docker installer for a variety of reasons. Mostly, because I want to know what exactly is going on on my machine. So I played around a bit and here is the bits and pieces installer if you decide against the one-for-all solution. Start with the virtualization solution. We need something like that on Windows, because it just can't run Linux and this is what Docker is based on. At least for now. So, get VirtualBox and ensure that version 4.3.18 is correctly installed on your system (VirtualBox-4.3.18-96516-Win.exe, 105 MB). WARNING: There is a strange issue, when you run Windows itself in Virtualbox. You might run into an issue with starting the host. And while you're at it, go and get the Docker Windows Client. The other is to grab the final from the test servers as a direct download (docker-1.6.0.exe, x86_64, 7.5MB). Rename to "docker" and put it into a folder of your choice (I assume it will be c:\docker\. Now you also need to download Docker Machine, which is another single executable (docker-machine_windows-amd64.exe, 11.5MB). Rename to "docker-machine" and put it into the same folder. Now add this folder to your PATH: set PATH=%PATH%;C:\docker If you change your standard PATH environment variable, this might safe your from a lot of typing. That's it. Now you're ready to create your first Machine managed Docker Host. Create Your Docker Host With Machine All you need is a simple command: docker-machine create --driver virtualbox dev And the output should state: ←[34mINFO←[0m[0000] Creating SSH key... ←[34mINFO←[0m[0001] Creating VirtualBox VM... ←[34mINFO←[0m[0016] Starting VirtualBox VM... ←[34mINFO←[0m[0022] Waiting for VM to start... ←[34mINFO←[0m[0076] "dev" has been created and is now the active machine. ←[34mINFO←[0m[0076] To point your Docker client at it, run this in your shell: eval "$(docker-machine.exe env dev)" This means, you just created a Docker Host using the VirtualBox provider and the name “dev”. Now you need to find out on which IP address the host is running. docker-machine ip 192.168.99.102 If you want to configure your environment variables, needed by the client more easy, just use the following command: docker-machine env dev export DOCKER_TLS_VERIFY=1 export DOCKER_CERT_PATH="C:\\Users\\markus\\.docker\\machine\\machines\\dev" export DOCKER_HOST=tcp://192.168.99.102:2376 Which outputs the Linux version of environment variable definition. All you have to do is to change the "export" keyword to "set", remove the " and the double back-slashes and you are ready to go. C:\Users\markus\Downloads>set DOCKER_TLS_VERIFY=1 C:\Users\markus\Downloads>set DOCKER_CERT_PATH=C:\Users\markus\.docker\machine\machines\dev C:\Users\markus\Downloads>set DOCKER_HOST=tcp://192.168.99.102:2376 Time to test our Docker Client And here we go now run WildFly on your freshly created host: docker run -it -p 8080:8080 jboss/wildfly Watch the container being downloaded and check, that it is running by redirecting your browser to http://192.168.99.102:8080/. Congratulations on having setup your very first docker host with Maschine on Windows.
May 12, 2015
by Markus Eisele
· 20,190 Views
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Collecting Transaction Per Minute from SQL Server and HammerDB
SQL Server script file can be created to run in a loop collecting for a given amount of time at a specified interval.
May 11, 2015
by Greg Schulz
· 10,326 Views
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8 Questions You Need to Ask About Microservices, Containers & Docker in 2015
In containers and microservices, we’re facing the greatest potential change in how we deliver and run software services since the arrival of virtual machines.
May 9, 2015
by Andrew Phillips
· 15,058 Views · 1 Like
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Binding to Data Services with Spring Boot in Cloud Foundry
Written by Dave Syer on the Spring blog In this article we look at how to bind a Spring Boot application to data services (JDBC, NoSQL, messaging etc.) and the various sources of default and automatic behaviour in Cloud Foundry, providing some guidance about which ones to use and which ones will be active under what conditions. Spring Boot provides a lot of autoconfiguration and external binding features, some of which are relevant to Cloud Foundry, and many of which are not. Spring Cloud Connectors is a library that you can use in your application if you want to create your own components programmatically, but it doesn’t do anything “magical” by itself. And finally there is the Cloud Foundry java buildpack which has an “auto-reconfiguration” feature that tries to ease the burden of moving simple applications to the cloud. The key to correctly configuring middleware services, like JDBC or AMQP or Mongo, is to understand what each of these tools provides, how they influence each other at runtime, and and to switch parts of them on and off. The goal should be a smooth transition from local execution of an application on a developer’s desktop to a test environment in Cloud Foundry, and ultimately to production in Cloud Foundry (or otherwise) with no changes in source code or packaging, per the twelve-factor application guidelines. There is some simple source code accompanying this article. To use it you can clone the repository and import it into your favourite IDE. You will need to remove two dependencies from the complete project to get to the same point where we start discussing concrete code samples, namely spring-boot-starter-cloud-connectors and auto-reconfiguration. NOTE: The current co-ordinates for all the libraries being discussed are org.springframework.boot:spring-boot-*:1.2.3.RELEASE,org.springframework.boot:spring-cloud-*-connector:1.1.1.RELEASE,org.cloudfoundry:auto-reconfiguration:1.7.0.RELEASE. TIP: The source code in github includes a docker-compose.yml file (docs here). You can use that to create a local MySQL database if you don’t have one running already. You don’t actually need it to run most of the code below, but it might be useful to validate that it will actually work. Punchline for the Impatient If you want to skip the details, and all you need is a recipe for running locally with H2 and in the cloud with MySQL, then start here and read the rest later when you want to understand in more depth. (Similar options exist for other data services, like RabbitMQ, Redis, Mongo etc.) Your first and simplest option is to simply do nothing: do not define a DataSource at all but put H2 on the classpath. Spring Boot will create the H2 embedded DataSource for you when you run locally. The Cloud Foundry buildpack will detect a database service binding and create a DataSource for you when you run in the cloud. If you add Spring Cloud Connectors as well, your app will also work in other cloud platforms, as long as you include a connector. That might be good enough if you just want to get something working. If you want to run a serious application in production you might want to tweak some of the connection pool settings (e.g. the size of the pool, various timeouts, the important test on borrow flag). In that case the buildpack auto-reconfiguration DataSource will not meet your requirements and you need to choose an alternative, and there are a number of more or less sensible choices. The best choice is probably to create a DataSource explicitly using Spring Cloud Connectors, but guarded by the “cloud” profile: @Configuration @Profile("cloud") public class DataSourceConfiguration { @Bean public Cloud cloud() { return new CloudFactory().getCloud(); } @Bean @ConfigurationProperties(DataSourceProperties.PREFIX) public DataSource dataSource() { return cloud().getSingletonServiceConnector(DataSourceclass, null); } } You can use spring.datasource.* properties (e.g. in application.properties or a profile-specific version of that) to set the additional properties at runtime. The “cloud” profile is automatically activated for you by the buildpack. Now for the details. We need to build up a picture of what’s going on in your application at runtime, so we can learn from that how to make a sensible choice for configuring data services. Layers of Autoconfiguration Let’s take a a simple app with DataSource (similar considerations apply to RabbitMQ, Mongo, Redis): @SpringBootApplication public class CloudApplication { @Autowired private DataSource dataSource; public static void main(String[] args) { SpringApplication.run(CloudApplication.class, args); } } This is a complete application: the DataSource can be @Autowired because it is created for us by Spring Boot. The details of the DataSource (concrete class, JDBC driver, connection URL, etc.) depend on what is on the classpath. Let’s assume that the application uses Spring JDBC via the spring-boot-starter-jdbc (or spring-boot-starter-data-jpa), so it has aDataSource implementation available from Tomcat (even if it isn’t a web application), and this is what Spring Boot uses. Consider what happens when: Classpath contains H2 (only) in addition to the starters: the DataSource is the Tomcat high-performance pool from DataSourceAutoConfiguration and it connects to an in memory database “testdb”. Classpath contains H2 and MySQL: DataSource is still H2 (same as before) because we didn’t provide any additional configuration for MySQL and Spring Boot can’t guess the credentials for connecting. Add spring-boot-starter-cloud-connectors to the classpath: no change inDataSource because the Spring Cloud Connectors do not detect that they are running in a Cloud platform. The providers that come with the starter all look for specific environment variables, which they won’t find unless you set them, or run the app in Cloud Foundry, Heroku, etc. Run the application in “cloud” profile with spring.profiles.active=cloud: no change yet in the DataSource, but this is one of the things that the Java buildpack does when your application runs in Cloud Foundry. Run in “cloud” profile and provide some environment variables to simulate running in Cloud Foundry and binding to a MySQL service: VCAP_APPLICATION={"name":"application","instance_id":"FOO"} VCAP_SERVICES={"mysql":[{"name":"mysql","tags":["mysql"],"credentials":{"uri":"mysql://root:root@localhost/test"}]} (the “tags” provides a hint that we want to create a MySQL DataSource, the “uri” provides the location, and the “name” becomes a bean ID). The DataSource is now using MySQL with the credentials supplied by the VCAP_* environment variables. Spring Boot has some autoconfiguration for the Connectors, so if you looked at the beans in your application you would see a CloudFactory bean, and also the DataSource bean (with ID “mysql”). Theautoconfiguration is equivalent to adding @ServiceScan to your application configuration. It is only active if your application runs in the “cloud” profile, and only if there is no existing @Bean of type Cloud, and the configuration flagspring.cloud.enabled is not “false”. Add the “auto-reconfiguration” JAR from the Java buildpack (Maven co-ordinatesorg.cloudfoundry:auto-reconfiguration:1.7.0.RELEASE). You can add it as a local dependency to simulate running an application in Cloud Foundry, but it wouldn’t be normal to do this with a real application (this is just for experimenting with autoconfiguration). The auto-reconfiguration JAR now has everything it needs to create a DataSource, but it doesn’t (yet) because it detects that you already have a bean of type CloudFactory, one that was added by Spring Boot. Remove the explicit “cloud” profile. The profile will still be active when your app starts because the auto-reconfiguration JAR adds it back again. There is still no change to theDataSource because Spring Boot has created it for you via the @ServiceScan. Remove the spring-boot-starter-cloud-connectors dependency, so that Spring Boot backs off creating a CloudFactory. The auto-reconfiguration JAR actually has its own copy of Spring Cloud Connectors (all the classes with different package names) and it now uses them to create a DataSource (in a BeanFactoryPostProcessor). The Spring Boot autoconfigured DataSource is replaced with one that binds to MySQL via theVCAP_SERVICES. There is no control over pool properties, but it does still use the Tomcat pool if available (no support for Hikari or DBCP2). Remove the auto-reconfiguration JAR and the DataSource reverts to H2. TIP: use web and actuator starters with endpoints.health.sensitive=false to inspect the DataSource quickly through “/health”. You can also use the “/beans”, “/env” and “/autoconfig” endpoints to see what is going in in the autoconfigurations and why. NOTE: Running in Cloud Foundry or including auto-reconfiguration JAR in classpath locally both activate the “cloud” profile (for the same reason). The VCAP_* env vars are the thing that makes Spring Cloud and/or the auto-reconfiguration JAR create beans. NOTE: The URL in the VCAP_SERVICES is actually not a “jdbc” scheme, which should be mandatory for JDBC connections. This is, however, the format that Cloud Foundry normally presents it in because it works for nearly every language other than Java. Spring Cloud Connectors or the buildpack auto-reconfiguration, if they are creating a DataSource, will translate it into a jdbc:* URL for you. NOTE: The MySQL URL also contains user credentials and a database name which are valid for the Docker container created by the docker-compose.yml in the sample source code. If you have a local MySQL server with different credentials you could substitute those. TIP: If you use a local MySQL server and want to verify that it is connected, you can use the “/health” endpoint from the Spring Boot Actuator (included in the sample code already). Or you could create a schema-mysql.sql file in the root of the classpath and put a simple keep alive query in it (e.g. SELECT 1). Spring Boot will run that on startupso if the app starts successfully you have configured the database correctly. The auto-reconfiguration JAR is always on the classpath in Cloud Foundry (by default) but it backs off creating any DataSource if it finds a org.springframework.cloud.CloudFactorybean (which is provided by Spring Boot if the CloudAutoConfiguration is active). Thus the net effect of adding it to the classpath, if the Connectors are also present in a Spring Boot application, is only to enable the “cloud” profile. You can see it making the decision to skip auto-reconfiguration in the application logs on startup: 015-04-14 15:11:11.765 INFO 12727 --- [ main] urceCloudServiceBeanFactoryPostProcessor : Skipping auto-reconfiguring beans of type javax.sql.DataSource 2015-04-14 15:11:57.650 INFO 12727 --- [ main] ongoCloudServiceBeanFactoryPostProcessor : Skipping auto-reconfiguring beans of type org.springframework.data.mongodb.MongoDbFactory 2015-04-14 15:11:57.650 INFO 12727 --- [ main] bbitCloudServiceBeanFactoryPostProcessor : Skipping auto-reconfiguring beans of type org.springframework.amqp.rabbit.connection.ConnectionFactory 2015-04-14 15:11:57.651 INFO 12727 --- [ main] edisCloudServiceBeanFactoryPostProcessor : Skipping auto-reconfiguring beans of type org.springframework.data.redis.connection.RedisConnectionFactory ... etc. Create your own DataSource The last section walked through most of the important autoconfiguration features in the various libraries. If you want to take control yourself, one thing you could start with is to create your own instance of DataSource. You could do that, for instance, using aDataSourceBuilder which is a convenience class and comes as part of Spring Boot (it chooses an implementation based on the classpath): @SpringBootApplication public class CloudApplication { @Bean public DataSource dataSource() { return DataSourceBuilder.create().build(); } ... } The DataSource as we’ve defined it is useless because it doesn’t have a connection URL or any credentials, but that can easily be fixed. Let’s run this application as if it was in Cloud Foundry: with the VCAP_* environment variables and the auto-reconfiguration JAR but not Spring Cloud Connectors on the classpath and no explicit “cloud” profile. The buildpack activates the “cloud” profile, creates a DataSource and binds it to the VCAP_SERVICES. As already described briefly, it removes your DataSource completely and replaces it with a manually registered singleton (which doesn’t show up in the “/beans” endpoint in Spring Boot). Now add Spring Cloud Connectors back into the classpath the application and see what happens when you run it again. It actually fails on startup! What has happened? The@ServiceScan (from Connectors) goes and looks for bound services, and creates bean definitions for them. That’s a bit like the buildpack, but different because it doesn’t attempt to replace any existing bean definitions of the same type. So you get an autowiring error because there are 2 DataSources and no way to choose one to inject into your application in various places where one is needed. To fix that we are going to have to take control of the Cloud Connectors (or simply not use them). Using a CloudFactory to create a DataSource You can disable the Spring Boot autoconfiguration and the Java buildpack auto-reconfiguration by creating your own Cloud instance as a @Bean: @Bean public Cloud cloud() { return new CloudFactory().getCloud(); } @Bean @ConfigurationProperties(DataSourceProperties.PREFIX) public DataSource dataSource() { return cloud().getSingletonServiceConnector(DataSource.class, null); } Pros: The Connectors autoconfiguration in Spring Boot backed off so there is only oneDataSource. It can be tweaked using application.properties via spring.datasource.*properties, per the Spring Boot User Guide. Cons: It doesn’t work without VCAP_* environment variables (or some other cloud platform). It also relies on user remembering to ceate the Cloud as a @Bean in order to disable the autoconfiguration. Summary: we are still not in a comfortable place (an app that doesn’t run without some intricate wrangling of environment variables is not much use in practice). Dual Running: Local with H2, in the Cloud with MySQL There is a local configuration file option in Spring Cloud Connectors, so you don’t have to be in a real cloud platform to use them, but it’s awkward to set up despite being boiler plate, and you also have to somehow switch it off when you are in a real cloud platform. The last point there is really the important one because you end up needing a local file to run locally, but only running locally, and it can’t be packaged with the rest of the application code (for instance violates the twelve factor guidelines). So to move forward with our explicit @Bean definition it’s probably better to stick to mainstream Spring and Spring Boot features, e.g. using the “cloud” profile to guard the explicit creation of a DataSource: @Configuration @Profile("cloud") public class DataSourceConfiguration { @Bean public Cloud cloud() { return new CloudFactory().getCloud(); } @Bean @ConfigurationProperties(DataSourceProperties.PREFIX) public DataSource dataSource() { return cloud().getSingletonServiceConnector(DataSource.class, null); } } With this in place we have a solution that works smoothly both locally and in Cloud Foundry. Locally Spring Boot will create a DataSource with an H2 embedded database. In Cloud Foundry it will bind to a singleton service of type DataSource and switch off the autconfigured one from Spring Boot. It also has the benefit of working with any platform supported by Spring Cloud Connectors, so the same code will run on Heroku and Cloud Foundry, for instance. Because of the @ConfigurationProperties you can bind additional configuration to the DataSource to tweak connection pool properties and things like that if you need to in production. NOTE: We have been using MySQL as an example database server, but actually PostgreSQL is at least as compelling a choice if not more. When paired with H2 locally, for instance, you can put H2 into its “Postgres compatibility” mode and use the same SQL in both environments. Manually Creating a Local and a Cloud DataSource If you like creating DataSource beans, and you want to do it both locally and in the cloud, you could use 2 profiles (“cloud” and “local”), for example. But then you would have to find a way to activate the “local” profile by default when not in the cloud. There is already a way to do that built into Spring because there is always a default profile called “default” (by default). So this should work: @Configuration @Profile("default") // or "!cloud" public class LocalDataSourceConfiguration { @Bean @ConfigurationProperties(DataSourceProperties.PREFIX) public DataSource dataSource() { return DataSourceBuilder.create().build(); } } @Configuration @Profile("cloud") public class CloudDataSourceConfiguration { @Bean public Cloud cloud() { return new CloudFactory().getCloud(); } @Bean @ConfigurationProperties(DataSourceProperties.PREFIX) public DataSource dataSource() { return cloud().getSingletonServiceConnector(DataSource.class, null); } } The “default” DataSource is actually identical to the autoconfigured one in this simple example, so you wouldn’t do this unless you needed to, e.g. to create a custom concreteDataSource of a type not supported by Spring Boot. You might think it’s all getting a bit complicated, but in fact Spring Boot is not making it any harder, we are just dealing with the consequences of needing to control the DataSource construction in 2 environments. Using a Non-Embedded Database Locally If you don’t want to use H2 or any in-memory database locally, then you can’t really avoid having to configure it (Spring Boot can guess a lot from the URL, but it will need that at least). So at a minimum you need to set some spring.datasource.* properties (the URL for instance). That that isn’t hard to do, and you can easily set different values in different environments using additional profiles, but as soon as you do that you need to switch off the default values when you go into the cloud. To do that you could define thespring.datasource.* properties in a profile-specific file (or document in YAML) for the “default” profile, e.g. application-default.properties, and these will not be used in the “cloud” profile. A Purely Declarative Approach If you prefer not to write Java code, or don’t want to use Spring Cloud Connectors, you might want to try and use Spring Boot autoconfiguration and external properties (or YAML) files for everything. For example Spring Boot creates a DataSource for you if it finds the right stuff on the classpath, and it can be completely controlled through application.properties, including all the granular features on the DataSource that you need in production (like pool sizes and validation queries). So all you need is a way to discover the location and credentials for the service from the environment. The buildpack translates Cloud Foundry VCAP_*environment variables into usable property sources in the Spring Environment. Thus, for instance, a DataSource configuration might look like this: spring.datasource.url: ${cloud.services.mysql.connection.jdbcurl:jdbc:h2:mem:testdb} spring.datasource.username: ${cloud.services.mysql.connection.username:sa} spring.datasource.password: ${cloud.services.mysql.connection.password:} spring.datasource.testOnBorrow: true The “mysql” part of the property names is the service name in Cloud Foundry (so it is set by the user). And of course the same pattern applies to all kinds of services, not just a JDBCDataSource. Generally speaking it is good practice to use external configuration and in particular @ConfigurationProperties since they allow maximum flexibility, for instance to override using System properties or environment variables at runtime. Note: similar features are provided by Spring Boot, which provides vcap.services.*instead of cloud.services.*, so you actually end up with more than one way to do this. However, the JDBC urls are not available from the vcap.services.* properties (non-JDBC services work fine with tthe corresponding vcap.services.*credentials.url). One limitation of this approach is it doesn’t apply if the application needs to configure beans that are not provided by Spring Boot out of the box (e.g. if you need 2 DataSources), in which case you have to write Java code anyway, and may or may not choose to use properties files to parameterize it. Before you try this yourself, though, beware that actually it doesn’t work unless you also disable the buildpack auto-reconfiguration (and Spring Cloud Connectors if they are on the classpath). If you don’t do that, then they create a new DataSource for you and Spring Boot cannot bind it to your properties file. Thus even for this declarative approach, you end up needing an explicit @Bean definition, and you need this part of your “cloud” profile configuration: @Configuration @Profile("cloud") public class CloudDataSourceConfiguration { @Bean public Cloud cloud() { return new CloudFactory().getCloud(); } } This is purely to switch off the buildpack auto-reconfiguration (and the Spring Boot autoconfiguration, but that could have been disabled with a properties file entry). Mixed Declarative and Explicit Bean Definition You can also mix the two approaches: declare a single @Bean definition so that you control the construction of the object, but bind additional configuration to it using@ConfigurationProperties (and do the same locally and in Cloud Foundry). Example: @Configuration public class LocalDataSourceConfiguration { @Bean @ConfigurationProperties(DataSourceProperties.PREFIX) public DataSource dataSource() { return DataSourceBuilder.create().build(); } } (where the DataSourceBuilder would be replaced with whatever fancy logic you need for your use case). And the application.properties would be the same as above, with whatever additional properties you need for your production settings. A Third Way: Discover the Credentials and Bind Manually Another approach that lends itself to platform and environment independence is to declare explicit bean definitions for the @ConfigurationProperties beans that Spring Boot uses to bind its autoconfigured connectors. For instance, to set the default values for a DataSourceyou can declare a @Bean of type DataSourceProperties: @Bean @Primary public DataSourceProperties dataSourceProperties() { DataSourceProperties properties = new DataSourceProperties(); properties.setInitialize(false); return properties; } This sets a default value for the “initialize” flag, and allows other properties to be bound fromapplication.properties (or other external properties). Combine this with the Spring Cloud Connectors and you can control the binding of the credentials when a cloud service is detected: @Autowired(required="false") Cloud cloud; @Bean @Primary public DataSourceProperties dataSourceProperties() { DataSourceProperties properties = new DataSourceProperties(); properties.setInitialize(false); if (cloud != null) { List infos = cloud.getServiceInfos(RelationalServiceInfo.class); if (infos.size()==1) { RelationalServiceInfo info = (RelationalServiceInfo) infos.get(0); properties.setUrl(info.getJdbcUrl()); properties.setUsername(info.getUserName()); properties.setPassword(info.getPassword()); } } return properties; } and you still need to define the Cloud bean in the “cloud” profile. It ends up being quite a lot of code, and is quite unnecessary in this simple use case, but might be handy if you have more complicated bindings, or need to implement some logic to choose a DataSource at runtime. Spring Boot has similar *Properties beans for the other middleware you might commonly use (e.g. RabbitProperties, RedisProperties, MongoProperties). An instance of such a bean marked as @Primary is enough to reset the defaults for the autoconfigured connector. Deploying to Multiple Cloud Platforms So far, we have concentrated on Cloud Foundry as the only cloud platform in which to deploy the application. One of the nice features of Spring Cloud Connectors is that it supports other platforms, either out of the box or as extension points. Thespring-boot-starter-cloud-connectors even includes Heroku support. If you do nothing at all, and rely on the autoconfiguration (the lazy programmer’s approach), then your application will be deployable in all clouds where you have a connector on the classpath (i.e. Cloud Foundry and Heroku if you use the starter). If you take the explicit @Bean approach then you need to ensure that the “cloud” profile is active in the non-Cloud Foundry platforms, e.g. through an environment variable. And if you use the purely declarative approach (or any combination involving properties files) you need to activate the “cloud” profile and probably also another profile specific to your platform, so that the right properties files end up in theEnvironment at runtime. Summary of Autoconfiguration and Provided Behaviour Spring Boot provides DataSource (also RabbitMQ or Redis ConnectionFactory, Mongo etc.) if it finds all the right stuff on the classpath. Using the “spring-boot-starter-*” dependencies is sufficient to activate the behaviour. Spring Boot also provides an autowirable CloudFactory if it finds Spring Cloud Connectors on the classpath (but switches off only if it finds a @Bean of type Cloud). The CloudAutoConfiguration in Spring Boot also effectively adds a @CloudScan to your application, which you would want to switch off if you ever needed to create your ownDataSource (or similar). The Cloud Foundry Java buildpack detects a Spring Boot application and activates the “cloud” profile, unless it is already active. Adding the buildpack auto-reconfiguration JAR does the same thing if you want to try it locally. Through the auto-reconfiguration JAR, the buildpack also kicks in and creates aDataSource (ditto RabbitMQ, Redis, Mongo etc.) if it does not find a CloudFactory bean or a Cloud bean (amongst others). So including Spring Cloud Connectors in a Spring Boot application switches off this part of the “auto-reconfiguration” behaviour (the bean creation). Switching off the Spring Boot CloudAutoConfiguration is easy, but if you do that, you have to remember to switch off the buildpack auto-reconfiguration as well if you don’t want it. The only way to do that is to define a bean definition (can be of type Cloud orCloudFactory for instance). Spring Boot binds application.properties (and other sources of external properties) to@ConfigurationProperties beans, including but not limited to the ones that it autoconfigures. You can use this feature to tweak pool properties and other settings that need to be different in production environments. General Advice and Conclusion We have seen quite a few options and autoconfigurations in this short article, and we’ve only really used thee libraries (Spring Boot, Spring Cloud Connectors, and the Cloud Foundry buildpack auto-reconfiguration JAR) and one platform (Cloud Foundry), not counting local deployment. The buildpack features are really only useful for very simple applications because there is no flexibility to tune the connections in production. That said it is a nice thing to be able to do when prototyping. There are only three main approaches if you want to achieve the goal of deploying the same code locally and in the cloud, yet still being able to make necessary tweaks in production: Use Spring Cloud Connectors to explicitly create DataSource and other middleware connections and protect those @Beans with @Profile("cloud"). The approach always works, but leads to more code than you might need for many applications. Use the Spring Boot default autoconfiguration and declare the cloud bindings usingapplication.properties (or in YAML). To take full advantage you have to expliccitly switch off the buildpack auto-reconfiguration as well. Use Spring Cloud Connectors to discover the credentials, and bind them to the Spring Boot@ConfigurationProperties as default values if present. The three approaches are actually not incompatible, and can be mixed using@ConfigurationProperties to provide profile-specific overrides of default configuration (e.g. for setting up connection pools in a different way in a production environment). If you have a relatively simple Spring Boot application, the only way to choose between the approaches is probably personal taste. If you have a non-Spring Boot application then the explicit @Bean approach will win, and it may also win if you plan to deploy your application in more than one cloud platform (e.g. Heroku and Cloud Foundry). NOTE: This blog has been a journey of discovery (who knew there was so much to learn?). Thanks go to all those who helped with reviews and comments, in particularScott Frederick, who spotted most of the mistakes in the drafts and always had time to look at a new revision.
May 6, 2015
by Pieter Humphrey
· 27,108 Views · 2 Likes
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Why Run Your Microservices on a PaaS
[This article by Chris Haddad comes to you from the DZone Guide to Cloud Development - 2015 Edition. For more information—including in-depth articles from industry experts, best solutions for PaaS, iPaaS, IaaS, and MBaaS, and more—click the link below to download your free copy of the guide.] Microservices can be understood from two angles. First, the differential: teams that take a microservice design approach divide business solutions into distinct, full-stack business services owned by autonomous teams. Second, the integral: microservice-based applications weave multiple atomic microservices into holistic user experiences. Unfortunately, traditional application delivery models and traditional middleware infrastructure do not address microservice-specific demands for on-demand provisioning, dynamic composition, and service level management. On the other hand, the Platform-as-a-Service (PaaS) model addresses these demands perfectly. Running microservices on a PaaS fabric decreases solution fragility, reduces operational burden, and enhances developer productivity. To understand why, we’ll first review how microservices separate concerns from both business and object-oriented design perspectives. Second, we’ll consider how microservice-based design can complicate deployment as applications scale dynamically. Third, we’ll focus on how a PaaS environment helps to solve many of the problems both addressed and introduced by microservices-based architectures — in other words, why PaaS and microservices are a match made in heaven. Microservices: Separating Concerns By Business Solution A microservice approach decomposes monolithic applications according to the single responsibility pattern. In a microservice solution, each microservice interface delivers discrete business capabilities (e.g. customer profile, product catalogue, inventory, order, billing, fulfillment) within a well-defined, bounded context. The atomic microservice interfaces reside on separate and distinct full-stack application platforms that contain separate database storage, integration flows, and web application hosting. By separating concerns onto separate full-stack platforms and not sharing database instances or web application hosts across services, every team is free to choose different runtime languages and frameworks for its own microservice. Also, every team is free to evolve its data schemas, application frameworks, and business logic without impacting other teams. Because microservices are a relatively new design approach, many development teams may have the misconception that creating a microservice-based solution requires simply deploying small web services in containers. But this doesn’t cut quite deep enough. The correct approach is to evolve your monolithic design by applying service-oriented principles (i.e. encapsulation, loose coupling, separation of concerns) in conjunction with domain-driven design techniques and dynamic runtime application composition. For example, in a typical ecommerce scenario, a development team applies the bounded context pattern and single responsibility pattern to refactor a monolithic application into units distinguished by business capability (see Figure 2). By creating a user experience from loosely coupled services instead of tightly coupled native-language business objects, teams have more independence to develop, evolve, and deploy each business capability separately. Obviously, the microservice design approach works best for (a) greenfield projects or (b) modernization efforts where teams focus on refactoring monolithic application assets. The Microservice Execution Trap Although a microservice approach decouples development dependencies and speeds up development iterations, microservices also create a challenging environment for high-performance scaling and reliable runtime execution. More complex, loosely coupled, and dynamic environments distribute business capabilities over the entire network. Even a task as simple as responding to a single web application page request may spread out across several microservice instances residing on a distributed network topology. Martin Fowler and Stefan Tilkov (both microservice proponents) warn teams that successfully implementing a microservice approach requires choosing platforms that decrease solution fragility and reduce operational burdens. What Platform-as-a-Service Offers Platform-as-a-Service environments reduce microservice operational burdens when infrastructure-as-code and declarative policies are used to eliminate all manual actions and increase runtime quality of service (i.e. reliability, availability, scalability, and performance). The appropriate PaaS environment will automatically deploy, provision, and link full-stack microservices. In a microservice architecture, teams want to rapidly release new versions and perform A/B testing across versions. When teams define instance dependencies, scaling properties, and security policies as PaaS metadata or code scripts, the runtime fabric can reduce manual effort and increase release confidence. With a DevOps- friendly PaaS, the team can experiment with new service versions and safely rollback to a prior stable release if a problem arises. Because microservices are full-stack silos *1* that can be composed of multiple server instances (e.g. web server, database, load balancer, integration server), a PaaS can reduce deployment complexity by automatically spinning up and linking all instances. Linking may require discovering instance locations, dynamically initializing network routes, and auto-configuring connection strings based on service version or tenant. A traditional application will compose business functions and user experience by statically linking class files and shared object libraries. In contrast, microservice- based applications use service composition to connect available microservices endpoints and realize a fully functional application. While many microservice proponents promote microservice-based interactions by “smart endpoints through dumb pipes, ‘ effective service composition requires smart infrastructure building blocks to bootstrap and maintain connections between services and consumers. The right PaaS solves these problems. Infrastructure building blocks will register service endpoint locations, associate metadata and policies, connect clients, circuit break around failures, correlate inter-service calls, and load balance traffic. A microservice-friendly PaaS will provide service registries, metadata services, discovery services, and service virtualization gateways. In the pipe, circuit breakers will automatically route traffic on failover or overload. Smart endpoint code will dynamically connect with microservices based on discovery service responses and negotiated quality of service parameters. Rather than being hard-coded to a specific service hostname and URI, endpoint code will query for microservice location based on security assurances, performance guarantees, traffic load, service version, client tenancy, or business domain. When services are unavailable or underperform, smart endpoints will follow the tolerant reader pattern and gracefully degrade experience or proactively recover. A few recovery options include reading from local caches or circuit tripping to backup service endpoints. In conjunction with smart endpoint actions, a smart PaaS will spin up new microservice endpoints and full-stack instances based on service level management metrics. By following microservice architecture best practices, teams create anti-fragile applications that not only withstand a shock, but also improve performance and quality of service when stressed or experiencing failures. To drive this non-intuitive behavior, the underlying platform environment must be ready to scale, repair, and reconnect services. PaaS service level management components will create more resilient and anti-fragile microservices by monitoring performance, elastically provisioning instances, and dynamically re-routing traffic. Scaling an anti-fragile microservice is more difficult than scaling a web application. The PaaS should distribute microservice instances across multiple availability zones and dynamically adjust traffic to reduce latency and response time. Because transient microservice instances will rapidly start, stop, and change location, the service management layer must be completely automated and integrated with routing services. A PaaS environment will deliver the service level management, dynamic service composition, circuit breakers, and on-demand provisioning functions required to overcome the complexity inherent within a distributed microservice-based application architecture. Running microservices on a PaaS fabric will decrease solution fragility, reduce operational burden, and enhance developer productivity. If you are pursuing a microservice design approach, make sure you choose a microservice- friendly PaaS. DOWNLOAD YOUR FREE COPY TODAY
May 5, 2015
by Chris Haddad
· 12,092 Views · 2 Likes
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A Look at Nanomsg and Scalability Protocols (Why ZeroMQ Shouldn’t Be Your First Choice)
Earlier this month, I explored ZeroMQ and how it proves to be a promising solution for building fast, high-throughput, and scalable distributed systems. Despite lending itself quite well to these types of problems, ZeroMQ is not without its flaws. Its creators have attempted to rectify many of these shortcomings through spiritual successors Crossroads I/O and nanomsg. The now-defunct Crossroads I/O is a proper fork of ZeroMQ with the true intention being to build a viable commercial ecosystem around it. Nanomsg, however, is a reimagining of ZeroMQ—a complete rewrite in C1. It builds upon ZeroMQ’s rock-solid performance characteristics while providing several vital improvements, both internal and external. It also attempts to address many of the strange behaviors that ZeroMQ can often exhibit. Today, I’ll take a look at what differentiates nanomsg from its predecessor and implement a use case for it in the form of service discovery. Nanomsg vs. ZeroMQ A common gripe people have with ZeroMQ is that it doesn’t provide an API for new transport protocols, which essentially limits you to TCP, PGM, IPC, and ITC. Nanomsg addresses this problem by providing a pluggable interface for transports and messaging protocols. This means support for new transports (e.g. WebSockets) and new messaging patterns beyond the standard set of PUB/SUB, REQ/REP, etc. Nanomsg is also fully POSIX-compliant, giving it a cleaner API and better compatibility. No longer are sockets represented as void pointers and tied to a context—simply initialize a new socket and begin using it in one step. With ZeroMQ, the context internally acts as a storage mechanism for global state and, to the user, as a pool of I/O threads. This concept has been completely removed from nanomsg. In addition to POSIX compliance, nanomsg is hoping to be interoperable at the API and protocol levels, which would allow it to be a drop-in replacement for, or otherwise interoperate with, ZeroMQ and other libraries which implement ZMTP/1.0 and ZMTP/2.0. It has yet to reach full parity, however. ZeroMQ has a fundamental flaw in its architecture. Its sockets are not thread-safe. In and of itself, this is not problematic and, in fact, is beneficial in some cases. By isolating each object in its own thread, the need for semaphores and mutexes is removed. Threads don’t touch each other and, instead, concurrency is achieved with message passing. This pattern works well for objects managed by worker threads but breaks down when objects are managed in user threads. If the thread is executing another task, the object is blocked. Nanomsg does away with the one-to-one relationship between objects and threads. Rather than relying on message passing, interactions are modeled as sets of state machines. Consequently, nanomsg sockets are thread-safe. Nanomsg has a number of other internal optimizations aimed at improving memory and CPU efficiency. ZeroMQ uses a simple trie structure to store and match PUB/SUB subscriptions, which performs nicely for sub-10,000 subscriptions but quickly becomes unreasonable for anything beyond that number. Nanomsg uses a space-optimized trie called a radix tree to store subscriptions. Unlike its predecessor, the library also offers a true zero-copy API which greatly improves performance by allowing memory to be copied from machine to machine while completely bypassing the CPU. ZeroMQ implements load balancing using a round-robin algorithm. While it provides equal distribution of work, it has its limitations. Suppose you have two datacenters, one in New York and one in London, and each site hosts instances of “foo” services. Ideally, a request made for foo from New York shouldn’t get routed to the London datacenter and vice versa. With ZeroMQ’s round-robin balancing, this is entirely possible unfortunately. One of the new user-facing features that nanomsg offers is priority routing for outbound traffic. We avoid this latency problem by assigning priority one to foo services hosted in New York for applications also hosted there. Priority two is then assigned to foo services hosted in London, giving us a failover in the event that foos in New York are unavailable. Additionally, nanomsg offers a command-line tool for interfacing with the system called nanocat. This tool lets you send and receive data via nanomsg sockets, which is useful for debugging and health checks. Scalability Protocols Perhaps most interesting is nanomsg’s philosophical departure from ZeroMQ. Instead of acting as a generic networking library, nanomsg intends to provide the “Lego bricks” for building scalable and performant distributed systems by implementing what it refers to as “scalability protocols.” These scalability protocols are communication patterns which are an abstraction on top of the network stack’s transport layer. The protocols are fully separated from each other such that each can embody a well-defined distributed algorithm. The intention, as stated by nanomsg’s author Martin Sustrik, is to have the protocol specifications standardized through the IETF. Nanomsg currently defines six different scalability protocols: PAIR, REQREP, PIPELINE, BUS, PUBSUB, and SURVEY. PAIR (Bidirectional Communication) PAIR implements simple one-to-one, bidirectional communication between two endpoints. Two nodes can send messages back and forth to each other. REQREP (Client Requests, Server Replies) The REQREP protocol defines a pattern for building stateless services to process user requests. A client sends a request, the server receives the request, does some processing, and returns a response. PIPELINE (One-Way Dataflow) PIPELINE provides unidirectional dataflow which is useful for creating load-balanced processing pipelines. A producer node submits work that is distributed among consumer nodes. BUS (Many-to-Many Communication) BUS allows messages sent from each peer to be delivered to every other peer in the group. PUBSUB (Topic Broadcasting) PUBSUB allows publishers to multicast messages to zero or more subscribers. Subscribers, which can connect to multiple publishers, can subscribe to specific topics, allowing them to receive only messages that are relevant to them. SURVEY (Ask Group a Question) The last scalability protocol, and the one in which I will further examine by implementing a use case with, is SURVEY. The SURVEY pattern is similar to PUBSUB in that a message from one node is broadcasted to the entire group, but where it differs is that each node in the group responds to the message. This opens up a wide variety of applications because it allows you to quickly and easily query the state of a large number of systems in one go. The survey respondents must respond within a time window configured by the surveyor. Implementing Service Discovery As I pointed out, the SURVEY protocol has a lot of interesting applications. For example: What data do you have for this record? What price will you offer for this item? Who can handle this request? To continue exploring it, I will implement a basic service-discovery pattern. Service discovery is a pretty simple question that’s well-suited for SURVEY: what services are out there? Our solution will work by periodically submitting the question. As services spin up, they will connect with our service discovery system so they can identify themselves. We can tweak parameters like how often we survey the group to ensure we have an accurate list of services and how long services have to respond. This is great because 1) the discovery system doesn’t need to be aware of what services there are—it just blindly submits the survey—and 2) when a service spins up, it will be discovered and if it dies, it will be “undiscovered.” Here is the ServiceDiscovery class: from collections import defaultdict import random from nanomsg import NanoMsgAPIError from nanomsg import Socket from nanomsg import SURVEYOR from nanomsg import SURVEYOR_DEADLINE class ServiceDiscovery(object): def __init__(self, port, deadline=5000): self.socket = Socket(SURVEYOR) self.port = port self.deadline = deadline self.services = defaultdict(set) def bind(self): self.socket.bind('tcp://*:%s' % self.port) self.socket.set_int_option(SURVEYOR, SURVEYOR_DEADLINE, self.deadline) def discover(self): if not self.socket.is_open(): return self.services self.services = defaultdict(set) self.socket.send('service query') while True: try: response = self.socket.recv() except NanoMsgAPIError: break service, address = response.split('|') self.services[service].add(address) return self.services def resolve(self, service): providers = self.services[service] if not providers: return None return random.choice(tuple(providers)) def close(self): self.socket.close() The discover method submits the survey and then collects the responses. Notice we construct a SURVEYOR socket and set the SURVEYOR_DEADLINE option on it. This deadline is the number of milliseconds from when a survey is submitted to when a response must be received—adjust it accordingly based on your network topology. Once the survey deadline has been reached, a NanoMsgAPIError is raised and we break the loop. The resolve method will take the name of a service and randomly select an available provider from our discovered services. We can then wrap ServiceDiscovery with a daemon that will periodically run discover. import os import time from service_discovery import ServiceDiscovery DEFAULT_PORT = 5555 DEFAULT_DEADLINE = 5000 DEFAULT_INTERVAL = 2000 def start_discovery(port, deadline, interval): discovery = ServiceDiscovery(port, deadline=deadline) discovery.bind() print 'Starting service discovery [port: %s, deadline: %s, interval: %s]' \ % (port, deadline, interval) while True: print discovery.discover() time.sleep(interval / 1000) if __name__ == '__main__': port = int(os.environ.get('PORT', DEFAULT_PORT)) deadline = int(os.environ.get('DEADLINE', DEFAULT_DEADLINE)) interval = int(os.environ.get('INTERVAL', DEFAULT_INTERVAL)) start_discovery(port, deadline, interval) The discovery parameters are configured through environment variables which I inject into a Docker container. Services must connect to the discovery system when they start up. When they receive a survey, they should respond by identifying what service they provide and where the service is located. One such service might look like the following: import os from threading import Thread from nanomsg import REP from nanomsg import RESPONDENT from nanomsg import Socket DEFAULT_DISCOVERY_HOST = 'localhost' DEFAULT_DISCOVERY_PORT = 5555 DEFAULT_SERVICE_NAME = 'foo' DEFAULT_SERVICE_PROTOCOL = 'tcp' DEFAULT_SERVICE_HOST = 'localhost' DEFAULT_SERVICE_PORT = 9000 def register_service(service_name, service_address, discovery_host, discovery_port): socket = Socket(RESPONDENT) socket.connect('tcp://%s:%s' % (discovery_host, discovery_port)) print 'Starting service registration [service: %s %s, discovery: %s:%s]' \ % (service_name, service_address, discovery_host, discovery_port) while True: message = socket.recv() if message == 'service query': socket.send('%s|%s' % (service_name, service_address)) def start_service(service_name, service_protocol, service_port): socket = Socket(REP) socket.bind('%s://*:%s' % (service_protocol, service_port)) print 'Starting service %s' % service_name while True: request = socket.recv() print 'Request: %s' % request socket.send('The answer is 42') if __name__ == '__main__': discovery_host = os.environ.get('DISCOVERY_HOST', DEFAULT_DISCOVERY_HOST) discovery_port = os.environ.get('DISCOVERY_PORT', DEFAULT_DISCOVERY_PORT) service_name = os.environ.get('SERVICE_NAME', DEFAULT_SERVICE_NAME) service_host = os.environ.get('SERVICE_HOST', DEFAULT_SERVICE_HOST) service_port = os.environ.get('SERVICE_PORT', DEFAULT_SERVICE_PORT) service_protocol = os.environ.get('SERVICE_PROTOCOL', DEFAULT_SERVICE_PROTOCOL) service_address = '%s://%s:%s' % (service_protocol, service_host, service_port) Thread(target=register_service, args=(service_name, service_address, discovery_host, discovery_port)).start() start_service(service_name, service_protocol, service_port) Once again, we configure parameters through environment variables set on a container. Note that we connect to the discovery system with a RESPONDENT socket which then responds to service queries with the service name and address. The service itself uses a REP socket that simply responds to any requests with “The answer is 42,” but it could take any number of forms such as HTTP, raw socket, etc. The full code for this example, including Dockerfiles, can be found on GitHub. Nanomsg or ZeroMQ? Based on all the improvements that nanomsg makes on top of ZeroMQ, you might be wondering why you would use the latter at all. Nanomsg is still relatively young. Although it has numerous language bindings, it hasn’t reached the maturity of ZeroMQ which has a thriving development community. ZeroMQ has extensive documentation and other resources to help developers make use of the library, while nanomsg has very little. Doing a quick Google search will give you an idea of the difference (about 500,000 results for ZeroMQ to nanomsg’s 13,500). That said, nanomsg’s improvements and, in particular, its scalability protocols make it very appealing. A lot of the strange behaviors that ZeroMQ exposes have been resolved completely or at least mitigated. It’s actively being developed and is quickly gaining more and more traction. Technically, nanomsg has been in beta since March, but it’s starting to look production-ready if it’s not there already.
May 4, 2015
by Tyler Treat
· 16,072 Views · 1 Like
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Testing the NGINX Load Balancing Efficiency with ApacheBench
providing numerous prominent features and possibilities, jelastic allows you to host applications of any complexity and in such a way, gives your customers exactly what they need. however, when your project becomes highly demanded and visited, you face another problem – the necessity to increase your hardware productivity, as it should be able to handle and rapidly serve all of the incoming users’ requests. adding more resources will temporarily improve the situation, saving your server from the failure, but it won’t solve the root issue. and this results in the need to set up a clustering solution with embedded automatic load balancing. application cluster adjusting is quite easy with jelastic – just add a few more application server instances to your environment via the topology wizard . in addition, you’ll automatically get the nginx-balancer server enabled in front of your project. it will be responsible for the even load distribution among the stated number of app server nodes, performed by virtue of the http load balancing . in such a way, your application performance grows significantly, increasing the number of requests that can be served at one time. as a nice bonus, you decrease the risks of app inaccessibility, since if one server fails, all the rest continue working. in order to prove this scheme is that efficient, we’ll show you how to perform the load balancing testing with the help of apachebench (ab) tool. it provides a number of possibilities for testing the servers’ ability to cope with the increasing and changeable load. though ab was designed for apache installations testing, it can be used to benchmark any http server. so, let’s get started and test it in real time. create an environment and deploy the application 1. log into the jelastic platform and click the create environment button in the upper left corner of the dashboard. 2. the environment topology dialog window will instantly appear. here you can choose the desired programming language, application/web server and database. as we are going to test the apachephp server loading, select it and specify the resource usage limits by means of cloudlet sliders. then, attach the public ip address for this server and type the name of a new environment (e.g. balancer ). click create. 3. in just a minute your environment will appear at the dashboard. 4. once the environment is successfully created, you can deploy your application to it. here we’ll use the default helloworld.zip package, so you just need to deploy it to the desired environment with the corresponding button and confirm the deployment in the opened frame. control point testing to analyze the results you’ll need something to compare them with, so let’s make a control point test, using the created environment with just a single application server node. as it was mentioned above, we’ll use the apachebench (ab) tool for these purposes. it can generate a single-threaded load by sending the stated number of concurrent requests to a server. follow the steps below. 1. apachebench is a part of standard apache source distribution, so if you still don’t have it, run the following command through your terminal (or skip this step if you do). apt-get install apache2-utils detailed information about all the further used ab commands can be found by following this link . 2. enter the next line in the terminal: ab -n 500 -c 10 -g res1.tsv {url_to_your_env} substitute the {url_to_your_env} part with a link to your environment (e.g. http://balancer.jelastic.com/ in our case). in order to get it, click the open in browser button next to your environment and copy the corresponding url from the browser’s address bar. the specified command will send the total amount of 500 requests to the stated environment, which are divided into the packs of 10 concurrent requests at one time. all the results will be stored in the res1.tsv file inside your home folder (or enter the full path to the desired directory if you would like to change the file location). also, you can specify your custom parameters for the abovementioned command if you want. this test may take some time depending on the parameters you’ve set, therefore be patient. 3. the created file with results should look like the image below: change the environment configuration once you’ve got the initial information regarding application performance, it’s time to extend your environment’s topology and adjust it for the further testing. 1. return to the jelastic dashboard and click change environment topology for your balancer environment. 2. within the opened environment topology frame, add more application servers (e.g. one more apache instance) – use the + button in the horizontal scaling wizard section for that. nginx-balancer node will be automatically added to your environment as an entry point of your application. enable public ip for your load balancer and state the resource limits. clickapply to proceed. 3. when all of the required changes are successfully applied, you should disable the sticky sessions for the balancer server. otherwise, all the requests from one ip address will be redirected to the same instance of the application server. therefore, click the config button next to the nginx node. 4. navigate to the conf > nginx-jelastic.conf file. it’s not editable, so copy all its content and paste it to the nginx.conf file (located in the same folder) instead of include /etc/nginx/nginx-jelastic.conf; line (circled at the following image). 5. then, find two mentions of the sticky path parameter in the code (in the default upstream and upstreams list sections) and comment them as it is shown below. note: don’t miss the closing curly braces after those sticky path strings, they should be uncommented. 6. save the changes applied and restart the nginx server. testing balancer and compare results now let’s proceed directly to load balancing testing. 1. switch back to your terminal and run the ab testing again with the same parameters (except the file with results – specify another name for it, e.g. res2.tsv ). ab -n 500 -c 10 -g res2.tsv {url_to_your_env} 2. in order to clarify the obtained results, we’ll use the freely distributed gnuplot graphs utility. install it (if you haven’t done this before) and enter its shell with a gnuplot command. 3. after that, you need to set up the parameters for our future graph: set size 1, 1 set title “benchmark testing” set key left top set grid y set xlabel ‘requests’ set ylabel “response time (ms)” set datafile separator ‘\t’ 4. now you’re ready to compose the graph: plot “/home/res1.tsv” every ::2 using 5 title ‘single server’ with lines, “/home/res2.tsv” every ::2 using 5 title ‘two servers with lb’ with lines this plot command will build 2 graphs (separated with comma in the command body). let’s consider the used parameters in more details: “/home/resn.tsv” represents paths to the files with your testing results every ::2 operator defines that gnuplot will start building from the second row (i.e. the first row with headings will be skipped) using 5 means that the fifth ttime column (the total response time) will be used for graph building title ‘n’ option sets the particular graph name for the easier separation of the test results with lines is used for our graph to be a solid line you’ll get an automatically created and opened image similar to the following: due to the specified options, the red graph shows the performance of a single apacheserver without balancer (control point testing results) and the green one – of two servers with nginx load balancer (the second testing phase results). note: that the received testing results (response time for each sent requests) are shown in the ascending order, i.e. not chronologically. as you can see, while serving the low load, both configurations’ performance is almost the same, but as the number of requests is increasing, the response time for an environment with a single app server instance grows significantly, resulting in serving less requests simultaneously. so, if you are expecting a high load for your application server, increasing the number of its instances in a bundle with a balancing server will be the best way to keep your customers happy. register now and try it out for yourself. enjoy all of the advantages of the jelastic cloud!
May 1, 2015
by Tetiana Markova
· 6,066 Views · 1 Like
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Linux - Simulating Degraded Network Conditions
When testing an application or service, it can be very useful to simulate degraded network conditions. This allows you to see how they might perform for users.
April 30, 2015
by Corey Goldberg
· 5,174 Views
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Implementing Filter and Bakery Locks in Java
In order to understand how locks work, implementing custom locks is a good way. This post will show how to implement Filter and Bakery locks at Java (which are spin locks) and will compare their performances with Java's ReentrantLock. Filter and Bakery locks satisfies mutual exclusion and are starvation free algorithms also, Bakery lock is a first-come-first-served lock [1]. For performance testing, a counter value is incremented up to 10000000 with different lock types, different number of threads and different number of times. Test system configuration is: Intel Core I7 (has 8 cores – 4 of them are real), Ubuntu 14.04 LTS and Java 1.7.0_60. Filter lock has n-1 levels which maybe considered as “waiting rooms”. A thread must traverse this waiting rooms before acquiring the lock. There are two important properties for levels [2]: 1) At least one thread trying to enter level l succeeds. 2) If more than one thread is trying to enter level l, then at least one is blocked (i.e., continues to wait at that level). Filter lock is implemented as follows: /** * @author Furkan KAMACI */ public class Filter extends AbstractDummyLock implements Lock { /* Due to Java Memory Model, int[] not used for level and victim variables. Java programming language does not guarantee linearizability, or even sequential consistency, when reading or writing fields of shared objects [The Art of Multiprocessor Programming. Maurice Herlihy, Nir Shavit, 2008, pp.61.] */ private AtomicInteger[] level; private AtomicInteger[] victim; private int n; /** * Constructor for Filter lock * * @param n thread count */ public Filter(int n) { this.n = n; level = new AtomicInteger[n]; victim = new AtomicInteger[n]; for (int i = 0; i < n; i++) { level[i] = new AtomicInteger(); victim[i] = new AtomicInteger(); } } /** * Acquires the lock. */ @Override public void lock() { int me = ConcurrencyUtils.getCurrentThreadId(); for (int i = 1; i < n; i++) { level[me].set(i); victim[i].set(me); for (int k = 0; k < n; k++) { while ((k != me) && (level[k].get() >= i && victim[i].get() == me)) { //spin wait } } } } /** * Releases the lock. */ @Override public void unlock() { int me = ConcurrencyUtils.getCurrentThreadId(); level[me].set(0); } } Bakery lock algorithm maintains the first-come-first-served property by using a distributed version of the number-dispensing machines often found in bakeries: each thread takes a number in the doorway, and then waits until no thread with an earlier number is trying to enter it [3]. Bakery lock is implemented as follows: /** * @author Furkan KAMACI */ public class Bakery extends AbstractDummyLock implements Lock { /* Due to Java Memory Model, int[] not used for level and victim variables. Java programming language does not guarantee linearizability, or even sequential consistency, when reading or writing fields of shared objects [The Art of Multiprocessor Programming. Maurice Herlihy, Nir Shavit, 2008, pp.61.] */ private AtomicBoolean[] flag; private AtomicInteger[] label; private int n; /** * Constructor for Bakery lock * * @param n thread count */ public Bakery(int n) { this.n = n; flag = new AtomicBoolean[n]; label = new AtomicInteger[n]; for (int i = 0; i < n; i++) { flag[i] = new AtomicBoolean(); label[i] = new AtomicInteger(); } } /** * Acquires the lock. */ @Override public void lock() { int i = ConcurrencyUtils.getCurrentThreadId(); flag[i].set(true); label[i].set(findMaximumElement(label) + 1); for (int k = 0; k < n; k++) { while ((k != i) && flag[k].get() && ((label[k].get() < label[i].get()) || ((label[k].get() == label[i].get()) && k < i))) { //spin wait } } } /** * Releases the lock. */ @Override public void unlock() { flag[ConcurrencyUtils.getCurrentThreadId()].set(false); } /** * Finds maximum element within and {@link java.util.concurrent.atomic.AtomicInteger} array * * @param elementArray element array * @return maximum element */ private int findMaximumElement(AtomicInteger[] elementArray) { int maxValue = Integer.MIN_VALUE; for (AtomicInteger element : elementArray) { if (element.get() > maxValue) { maxValue = element.get(); } } return maxValue; } } For such kind of algorithms, it should be provided or used a thread id system which starts from 0 or 1 and increments one by one. Threads' names set appropriately for that purpose. It should also be considererd that: Java programming language does not guarantee linearizability, or even sequential consistency, when reading or writing fields of shared objects [4]. So, level and victim variables for Filter lock, flag and label variables for Bakery lock defined as atomic variables. For one, who wants to test effects of Java Memory Model can change that variables into int[] and boolean[] and run algorithm with more than 2 threads. Than, can see that algorithm will hang for either Filter or Bakery even threads are alive. To test algorithm performances, a custom counter class implemented which has a getAndIncrement method as follows: /** * gets and increments value up to a maximum number * * @return value before increment if it didn't exceed a defined maximum number. Otherwise returns maximum number. */ public long getAndIncrement() { long temp; lock.lock(); try { if (value >= maxNumber) { return value; } temp = value; value = temp + 1; } finally { lock.unlock(); } return temp; } There is a maximum number barrier to fairly test multiple application configurations. Consideration is that: there is a piece amount of work (incrementing a variable up to a desired number) and with different number of threads how fast you can finish it. So, for comparison, there should be a “job” equality. This approach also tests unnecessary work load with that piece of code: if (value >= maxNumber) { return value; } for multiple threads when it is compared an approach that calculating unit work performance of threads (i.e. does not putting a maximum barrier, iterating in a loop up to a maximum number and than dividing last value to thread number). This configuration used for performance comparison: Threads 1,2,3,4,5,6,7,8 Retry Count 20 Maximum Number 10000000 This is the chart of results which includes standard errors: First of all, when you run a block of code within Java several time, there is an internal optimization for codes. When algorithm is run multiple times and first output compared to second output this optimization's effect can be seen. First elapsed time mostly should be greater than second line because of that. For example: currentTry = 0, threadCount = 1, maxNumber = 10000000, lockType = FILTER, elapsedTime = 500 (ms) currentTry = 1, threadCount = 1, maxNumber = 10000000, lockType = FILTER, elapsedTime = 433 (ms) Conclusion: From the chart, it can bee seen that Bakery lock is faster than Filter Lock with a low standard error. Reason is Filter Lock's lock method. At Bakery Lock, as a faired approach threads runs one by one but at Filter Lock they computes with each other. Java's ReentrantLock has best when compared to others. On the other hand Filter Lock gets worse linearly but Bakery and ReentrantLock are not (Filter lock may have a linear graphic when it run with much more threads). More thread count does not mean less elapsed time. 2 threads maybe worse than 1 thread because of thread creating and locking/unlocking. When thread count starts to increase, elapsed time gets better for Bakery and ReentrantLock. However when thread count keep going to increase than it gets worse. Reason is real core number of the test computer which runs algorithms. Source code for implementing filter and bakery locks in Java can be downloaded from here: https://github.com/kamaci/filbak [1] The Art of Multiprocessor Programming. Maurice Herlihy, Nir Shavit, 2008, pp.31.-33. [2] The Art of Multiprocessor Programming. Maurice Herlihy, Nir Shavit, 2008, pp.28. [3] The Art of Multiprocessor Programming. Maurice Herlihy, Nir Shavit, 2008, pp.31. [4] The Art of Multiprocessor Programming. Maurice Herlihy, Nir Shavit, 2008, pp.61.
April 28, 2015
by Furkan Kamaci
· 9,208 Views · 2 Likes
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Diagnosing SST Errors with Percona XtraDB Cluster for MySQL
[This article was written by Stephane Combaudon] State Snapshot Transfer (SST) is used in Percona XtraDB Cluster (PXC) when a new node joins the cluster or to resync a failed node if Incremental State Transfer (IST) is no longer available. SST is triggered automatically but there is no magic: If it is not configured properly, it will not work and new nodes will never be able to join the cluster. Let’s have a look at a few classic issues. Port for SST is not open The donor and the joiner communicate on port 4444, and if the port is closed on one side, SST will always fail. You will see in the error log of the donor that SST is started: [...] 141223 16:08:48 [Note] WSREP: Node 2 (node1) requested state transfer from '*any*'. Selected 0 (node3)(SYNCED) as donor. 141223 16:08:48 [Note] WSREP: Shifting SYNCED -> DONOR/DESYNCED (TO: 6) 141223 16:08:48 [Note] WSREP: wsrep_notify_cmd is not defined, skipping notification. 141223 16:08:48 [Note] WSREP: Running: 'wsrep_sst_xtrabackup-v2 --role 'donor' --address '192.168.234.101:4444/xtrabackup_sst' --auth 'sstuser:s3cret' --socket '/var/lib/mysql/mysql.sock' --datadir '/var/lib/mysql/' --defaults-file '/etc/my.cnf' --gtid '04c085a1-89ca-11e4-b1b6-6b692803109b:6'' [...] But then nothing happens, and some time later you will see a bunch of errors: [...] 2014/12/23 16:09:52 socat[2965] E connect(3, AF=2 192.168.234.101:4444, 16): Connection timed out WSREP_SST: [ERROR] Error while getting data from donor node: exit codes: 0 1 (20141223 16:09:52.057) WSREP_SST: [ERROR] Cleanup after exit with status:32 (20141223 16:09:52.064) WSREP_SST: [INFO] Cleaning up temporary directories (20141223 16:09:52.068) 141223 16:09:52 [ERROR] WSREP: Failed to read from: wsrep_sst_xtrabackup-v2 --role 'donor' --address '192.168.234.101:4444/xtrabackup_sst' --auth 'sstuser:s3cret' --socket '/var/lib/mysql/mysql.sock' --datadir '/var/lib/mysql/' --defaults-file '/etc/my.cnf' --gtid '04c085a1-89ca-11e4-b1b6-6b692803109b:6' [...] On the joiner side, you will see a similar sequence: SST is started, then hangs and is finally aborted: [...] 141223 16:08:48 [Note] WSREP: Shifting PRIMARY -> JOINER (TO: 6) 141223 16:08:48 [Note] WSREP: Requesting state transfer: success, donor: 0 141223 16:08:49 [Note] WSREP: (f9560d0d, 'tcp://0.0.0.0:4567') turning message relay requesting off 141223 16:09:52 [Warning] WSREP: 0 (node3): State transfer to 2 (node1) failed: -32 (Broken pipe) 141223 16:09:52 [ERROR] WSREP: gcs/src/gcs_group.cpp:long int gcs_group_handle_join_msg(gcs_group_t*, const gcs_recv_msg_t*)():717: Will never receive state. Need to abort. The solution is of course to make sure that the ports are open on both sides. SST is not correctly configured Sometimes you will see an error like this on the donor: 141223 21:03:15 [Note] WSREP: Running: 'wsrep_sst_xtrabackup-v2 --role 'donor' --address '192.168.234.102:4444/xtrabackup_sst' --auth 'sstuser:s3cretzzz' --socket '/var/lib/mysql/mysql.sock' --datadir '/var/lib/mysql/' --defaults-file '/etc/my.cnf' --gtid 'e63f38f2-8ae6-11e4-a383-46557c71f368:0'' [...] WSREP_SST: [ERROR] innobackupex finished with error: 1. Check /var/lib/mysql//innobackup.backup.log (20141223 21:03:26.973) And if you look at innobackup.backup.log: 41223 21:03:26 innobackupex: Connecting to MySQL server with DSN 'dbi:mysql:;mysql_read_default_file=/etc/my.cnf;mysql_read_default_group=xtrabackup;mysql_socket=/var/lib/mysql/mysql.sock' as 'sstuser' (using password: YES). innobackupex: got a fatal error with the following stacktrace: at /usr//bin/innobackupex line 2995 main::mysql_connect('abort_on_error', 1) called at /usr//bin/innobackupex line 1530 innobackupex: Error: Failed to connect to MySQL server: DBI connect(';mysql_read_default_file=/etc/my.cnf;mysql_read_default_group=xtrabackup;mysql_socket=/var/lib/mysql/mysql.sock','sstuser',...) failed: Access denied for user 'sstuser'@'localhost' (using password: YES) at /usr//bin/innobackupex line 2979 What happened? The default SST method is xtrabackup-v2 and for it to work, you need to specify a username/password in the my.cnf file: [mysqld] wsrep_sst_auth=sstuser:s3cret And you also need to create the corresponding MySQL user: mysql> GRANT RELOAD, LOCK TABLES, REPLICATION CLIENT ON *.* TO 'sstuser'@'localhost' IDENTIFIED BY 's3cret'; So you should check that the user has been correctly created in MySQL and that wsrep_sst_auth is correctly set. Galera versions do not match Here is another set of errors you may see in the error log of the donor: 141223 21:14:27 [Warning] WSREP: unserialize error invalid flags 2: 71 (Protocol error) at gcomm/src/gcomm/datagram.hpp:unserialize():101 141223 21:14:30 [Warning] WSREP: unserialize error invalid flags 2: 71 (Protocol error) at gcomm/src/gcomm/datagram.hpp:unserialize():101 141223 21:14:33 [Warning] WSREP: unserialize error invalid flags 2: 71 (Protocol error) at gcomm/src/gcomm/datagram.hpp:unserialize():101 Here the issue is that you try to connect a node using Galera 2.x and a node running Galera 3.x. This can happen if you try to use a PXC 5.5 node and a PXC 5.6 node. The right solution is probably to understand why you ended up with such inconsistent versions and make sure all nodes are using the same Percona XtraDB Cluster version and Galera version. But if you know what you are doing, you can also instruct the node using Galera 3.x that it will communicate with Galera 2.x nodes by specifying in the my.cnf file: [mysqld] wsrep_provider_options="socket.checksum=1" Conclusion SST errors can have multiple reasons for occurring, and the best way to diagnose the issue is to have a look at the error log of the donor and the joiner. Galera is in general quite verbose so you can follow the progress of SST on both nodes and see where it fails. Then it is mostly about being able to interpret the error messages.
April 27, 2015
by Peter Zaitsev
· 11,869 Views
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Agrona's Threadsafe Offheap Buffers
Learn more about Agrona's Threadsafe offheap buffers, and how to increase performance.
April 24, 2015
by Richard Warburton
· 8,893 Views
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Why Elasticsearch is Suitable for Application Log Analytics
Handling Application Logs Enterprise application development using Web technologies has been around for a long time. In recent years we have seen a sharp increase in the deployment of such applications. This is partly due to the proliferation of ecommerce sites, social media sites, mobile application supporting sites, as well as the desire of enterprises to have their applications available 24x7. In most cases, such applications cater to huge load and are deployed on cloud infrastructure. Monitoring deployed applications is increasingly becoming a crucial task, as deployed applications are bound to fail, irrespective of the robust techniques used during development. Whenever an application fails, the most common resolution method starts by examining the application log. If the application has implemented logging properly, the logs can reveal the cause of application failure. Examination of log files is usually done by viewing the file using tools like vi, less, more, tail or grep. Another method is to download the file to a Windows system and viewing it using an editor like Notepad++. Engineers usually scan the log information to look for clues that point to the reasons for failure. Once the cause of failure is identified, suitable action is taken for restoring the application and/or service. The Key to Application Log Analytics This process, of logging onto a remote system and viewing logs is tedious. Additionally, many of the tools do not provide support to make the task of issue identification any simpler. Even when using tools like grep (if we know the pattern), we still need to view the logs in order to go through other information that has been logged, such as the log information that precedes the failure point. While it has always been possible to develop applications to parse application logs, the recent renewed interest in application log analytics is due to the acceptance of NoSQL-like technologies and the availability of standard tools to parse application logs. Though relational databases (RDBMS) have for many years provided the facility to store structured data, they are not well-suited for handling log data, as in many cases, the structure of the logged information is not the same across the file. This does not fit well in the rigidly defined world of an RDBMS. In comparison, NoSQL allows document flexibility and documents with different schemas can be stored in the same database / index / store. The ability to convert log data into a well-defined structure, as well as the ability to search, are key to implement a modern log analytics solution. In this document, we cover how Elasticsearch. Elasticsearch can store documents, giving us the benefit of structured storage without the overheads of a database system. The Suitability of Elasticsearch In the following subsections, we share our views as to why Elasticsearch is a suitable data store for an application log analytics solution. Elasticsearch is part of a popular trio of tools, commonly known as ELK. Of these, L stands for Logstash, the log parser; E stands for Elasticsearch, the document store; and K stands for Kibana, the visualization tool. Storing Documents Logstash can be used to parse plain text data into structured text. Once data has some structure, it becomes easy to find information by enabling search on it. While parsing application logs is not a challenge, the challenge has been in storing the data and enabling search on it. Most prior solutions have used an RDBMS for storage, but the varying structure and textual nature of application logs makes it difficult to use an RDBMS table structure to store data. RDBMSs are not geared toward ‘search’. They are geared for maintaining a ‘single value of truth’ for the data, defining relations between the data, ensuring their consistency and so on. Search is also not a strong point for RDBMSs as they use exact matches for values, while Elasticsearch supports exact matches as well as partial matches. It also supports document scoring, which attaches a confidence factor to the documents located. Elasticsearch supports documents in JSON format and uses the NoSQL philosophy for document storage. This has the advantage of allowing a flexible schema for the data. Unlike an RDBMS, Elasticsearch is a search engine at heart and hence is built for the same. Though Elasticsearch uses NoSQL for storing documents, it does not provide robust methods to update stored data. Not supporting updates is a serious disadvantage in most cases. In the case of application logs, not supporting updates actually works in favour of Elasticsearch. In case of machine logs, updates are not really required. Application logs are generated from a debugging perspective – having data handy for debugging purposes in the event of application crash or incorrect execution. They usually record important events from application execution and provide additional information to allow application developers to identify the reasons for failure. Additionally, existing information in application logs is rarely, if ever, updated. New information is continually being written to the logs, with no need to refer to old information. This plays to Elasticsearch’s strength, which is able to ingest and index new information very quickly. Search One of the easiest ways of locating information from large volumes of logs is to perform a search. Elasticsearch is well suited not only to handle search, it also supports huge volume of data, using distributed computing (implemented using Shards). While Kibana is one of the commonly used tools to display and visualize information stored in Elasticsearch, it is more suited to display standard charts like bar chart, column chart and pie chart. If the features provided by Kibana are not enough, we can always use Elasticsearch’s REST API support and it’s Query DSL (Domain-Specific Language), to search for required information. The Query DSL and the result of the query are in JSON format. Though this format makes it easy for applications to parse and process, users would need a friendly user interface to interact with the data. Handling Voluminous Data Elasticsearch supports distributed search out of the box – using the concept of ‘shards’. A shard is a single Lucene instance and is managed by Elasticsearch. Two types of shards, namely ‘primary shard’ and ‘replica shard’ are supported. By default, a document is first indexed on the primary shard and then on the replica shards. The number of primary shards can be specified, to cater to the expected volume. By default, Elasticsearch creates five shards for an index. But, once the number of primary shards is decided, it cannot be changed. A replica shards are copies the primary shard. They are used to handle fail-over and the increase performance. While performance across voluminous data can be handled by sharding, it is important to note that shards, once created for an index, cannot be changed. Thus, the sharding strategy of the data has to be decided in advance, after an assessment of the data and an estimation of its growth. In the case of application logs, the sharding strategy can be based on the application name, the business unit ID, the application OD or the application’s geolocation, just to name a few. Analytics By storing data in a structure, analytics can be enabled on the data. Not only can application perform a simple search, it is also possible to restrict the search for specific terms or over a specified time period. Structured storage also makes it easier to develop reports with well-defined visualizations, which in turn makes it easy to understand the current state of applications. It is also possible to perform various analytics operations like time series analysis using the timestamp and identification of patterns from the data using machine learning techniques (assuming, we have the right kind of data in the logs). Though Elasticsearch does not provide built-in support for analytics, applications can benefit from its fast search capability and also from its ability to handle voluminous data sets. In Closing One of the main hurdles for application logs has been the ability to search for information from the huge volume of data. By parsing application log files using Logstash, we can convert a flat file into structured data. Structured data, once stored in Elasticsearch, is easier to search and locate. Visualizations and business logic for generating alerts and tickets is easier to develop on structured data. Elasticsearch, which stores and searches documents, along with its ability to scale over huge volume of data, is a good candidate for inclusion in an application log analytics solution.
April 22, 2015
by Bipin Patwardhan
· 11,728 Views · 2 Likes
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Using Apache Kafka for Integration and Data Processing Pipelines with Spring
written by josh long on the spring blog applications generated more and more data than ever before and a huge part of the challenge - before it can even be analyzed - is accommodating the load in the first place. apache’s kafka meets this challenge. it was originally designed by linkedin and subsequently open-sourced in 2011. the project aims to provide a unified, high-throughput, low-latency platform for handling real-time data feeds. the design is heavily influenced by transaction logs. it is a messaging system, similar to traditional messaging systems like rabbitmq, activemq, mqseries, but it’s ideal for log aggregation, persistent messaging, fast (_hundreds_ of megabytes per second!) reads and writes, and can accommodate numerous clients. naturally, this makes it perfect for cloud-scale architectures! kafka powers many large production systems . linkedin uses it for activity data and operational metrics to power the linkedin news feed, and linkedin today, as well as offline analytics going into hadoop. twitter uses it as part of their stream-processing infrastructure. kafka powers online-to-online and online-to-offline messaging at foursquare. it is used to integrate foursquare monitoring and production systems with hadoop-based offline infrastructures. square uses kafka as a bus to move all system events through square’s various data centers. this includes metrics, logs, custom events, and so on. on the consumer side, it outputs into splunk, graphite, or esper-like real-time alerting. netflix uses it for 300-600bn messages per day. it’s also used by airbnb, mozilla, goldman sachs, tumblr, yahoo, paypal, coursera, urban airship, hotels.com, and a seemingly endless list of other big-web stars. clearly, it’s earning its keep in some powerful systems! installing apache kafka there are many different ways to get apache kafka installed. if you’re on osx, and you’re using homebrew, it can be as simple as brew install kafka . you can also download the latest distribution from apache . i downloaded kafka_2.10-0.8.2.1.tgz , unzipped it, and then within you’ll find there’s a distribution of apache zookeeper as well as kafka, so nothing else is required. i installed apache kafka in my $home directory, under another directory, bin , then i created an environment variable, kafka_home , that points to $home/bin/kafka . start apache zookeeper first, specifying where the configuration properties file it requires is: $kafka_home/bin/zookeeper-server-start.sh $kafka_home/config/zookeeper.properties the apache kafka distribution comes with default configuration files for both zookeeper and kafka, which makes getting started easy. you will in more advanced use cases need to customize these files. then start apache kafka. it too requires a configuration file, like this: $kafka_home/bin/kafka-server-start.sh $kafka_home/config/server.properties the server.properties file contains, among other things, default values for where to connect to apache zookeeper ( zookeeper.connect ), how much data should be sent across sockets, how many partitions there are by default, and the broker id ( broker.id - which must be unique across a cluster). there are other scripts in the same directory that can be used to send and receive dummy data, very handy in establishing that everything’s up and running! now that apache kafka is up and running, let’s look at working with apache kafka from our application. some high level concepts.. a kafka broker cluster consists of one or more servers where each may have one or more broker processes running. apache kafka is designed to be highly available; there are no master nodes. all nodes are interchangeable. data is replicated from one node to another to ensure that it is still available in the event of a failure. in kafka, a topic is a category, similar to a jms destination or both an amqp exchange and queue. topics are partitioned, and the choice of which of a topic’s partition a message should be sent to is made by the message producer. each message in the partition is assigned a unique sequenced id, its offset . more partitions allow greater parallelism for consumption, but this will also result in more files across the brokers. producers send messages to apache kafka broker topics and specify the partition to use for every message they produce. message production may be synchronous or asynchronous. producers also specify what sort of replication guarantees they want. consumers listen for messages on topics and process the feed of published messages. as you’d expect if you’ve used other messaging systems, this is usually (and usefully!) asynchronous. like spring xd and numerous other distributed system, apache kafka uses apache zookeeper to coordinate cluster information. apache zookeeper provides a shared hierarchical namespace (called znodes ) that nodes can share to understand cluster topology and availability (yet another reason that spring cloud has forthcoming support for it..). zookeeper is very present in your interactions with apache kafka. apache kafka has, for example, two different apis for acting as a consumer. the higher level api is simpler to get started with and it handles all the nuances of handling partitioning and so on. it will need a reference to a zookeeper instance to keep the coordination state. let’s turn now turn to using apache kafka with spring. using apache kafka with spring integration the recently released apache kafka 1.1 spring integration adapter is very powerful, and provides inbound adapters for working with both the lower level apache kafka api as well as the higher level api. the adapter, currently, is xml-configuration first, though work is already underway on a spring integration java configuration dsl for the adapter and milestones are available. we’ll look at both here, now. to make all these examples work, i added the libs-milestone-local maven repository and used the following dependencies: org.apache.kafka:kafka_2.10:0.8.1.1 org.springframework.boot:spring-boot-starter-integration:1.2.3.release org.springframework.boot:spring-boot-starter:1.2.3.release org.springframework.integration:spring-integration-kafka:1.1.1.release org.springframework.integration:spring-integration-java-dsl:1.1.0.m1 using the spring integration apache kafka with the spring integration xml dsl first, let’s look at how to use the spring integration outbound adapter to send message instances from a spring integration flow to an external apache kafka instance. the example is fairly straightforward: a spring integration channel named inputtokafka acts as a conduit that forwards message messages to the outbound adapter, kafkaoutboundchanneladapter . the adapter itself can take its configuration from the defaults specified in the kafka:producer-context element or it from the adapter-local configuration overrides. there may be one or many configurations in a given kafka:producer-context element. here’s the java code from a spring boot application to trigger message sends using the outbound adapter by sending messages into the incoming inputtokafka messagechannel . package xml; import org.apache.commons.logging.log; import org.apache.commons.logging.logfactory; import org.springframework.beans.factory.annotation.qualifier; import org.springframework.boot.commandlinerunner; import org.springframework.boot.springapplication; import org.springframework.boot.autoconfigure.springbootapplication; import org.springframework.context.annotation.bean; import org.springframework.context.annotation.dependson; import org.springframework.context.annotation.importresource; import org.springframework.integration.config.enableintegration; import org.springframework.messaging.messagechannel; import org.springframework.messaging.support.genericmessage; @springbootapplication @enableintegration @importresource("/xml/outbound-kafka-integration.xml") public class demoapplication { private log log = logfactory.getlog(getclass()); @bean @dependson("kafkaoutboundchanneladapter") commandlinerunner kickoff(@qualifier("inputtokafka") messagechannel in) { return args -> { for (int i = 0; i < 1000; i++) { in.send(new genericmessage<>("#" + i)); log.info("sending message #" + i); } }; } public static void main(string args[]) { springapplication.run(demoapplication.class, args); } } using the new apache kafka spring integration java configuration dsl shortly after the spring integration 1.1 release, spring integration rockstar artem bilan got to work on adding a spring integration java configuration dsl analog and the result is a thing of beauty! it’s not yet ga (you need to add the libs-milestone repository for now), but i encourage you to try it out and kick the tires. it’s working well for me and the spring integration team are always keen on getting early feedback whenever possible! here’s an example that demonstrates both sending messages and consuming them from two different integrationflow s. the producer is similar to the example xml above. new in this example is the polling consumer. it is batch-centric, and will pull down all the messages it sees at a fixed interval. in our code, the message received will be a map that contains as its keys the topic and as its value another map with the partition id and the batch (in this case, of 10 records), of records read. there is a messagelistenercontainer -based alternative that processes messages as they come. package jc; import org.apache.commons.logging.log; import org.apache.commons.logging.logfactory; import org.springframework.beans.factory.annotation.autowired; import org.springframework.beans.factory.annotation.qualifier; import org.springframework.beans.factory.annotation.value; import org.springframework.boot.commandlinerunner; import org.springframework.boot.springapplication; import org.springframework.boot.autoconfigure.springbootapplication; import org.springframework.context.annotation.bean; import org.springframework.context.annotation.configuration; import org.springframework.context.annotation.dependson; import org.springframework.integration.integrationmessageheaderaccessor; import org.springframework.integration.config.enableintegration; import org.springframework.integration.dsl.integrationflow; import org.springframework.integration.dsl.integrationflows; import org.springframework.integration.dsl.sourcepollingchanneladapterspec; import org.springframework.integration.dsl.kafka.kafka; import org.springframework.integration.dsl.kafka.kafkahighlevelconsumermessagesourcespec; import org.springframework.integration.dsl.kafka.kafkaproducermessagehandlerspec; import org.springframework.integration.dsl.support.consumer; import org.springframework.integration.kafka.support.zookeeperconnect; import org.springframework.messaging.messagechannel; import org.springframework.messaging.support.genericmessage; import org.springframework.stereotype.component; import java.util.list; import java.util.map; /** * demonstrates using the spring integration apache kafka java configuration dsl. * thanks to spring integration ninja artem bilan * for getting the java configuration dsl working so quickly! * * @author josh long */ @enableintegration @springbootapplication public class demoapplication { public static final string test_topic_id = "event-stream"; @component public static class kafkaconfig { @value("${kafka.topic:" + test_topic_id + "}") private string topic; @value("${kafka.address:localhost:9092}") private string brokeraddress; @value("${zookeeper.address:localhost:2181}") private string zookeeperaddress; kafkaconfig() { } public kafkaconfig(string t, string b, string zk) { this.topic = t; this.brokeraddress = b; this.zookeeperaddress = zk; } public string gettopic() { return topic; } public string getbrokeraddress() { return brokeraddress; } public string getzookeeperaddress() { return zookeeperaddress; } } @configuration public static class producerconfiguration { @autowired private kafkaconfig kafkaconfig; private static final string outbound_id = "outbound"; private log log = logfactory.getlog(getclass()); @bean @dependson(outbound_id) commandlinerunner kickoff( @qualifier(outbound_id + ".input") messagechannel in) { return args -> { for (int i = 0; i < 1000; i++) { in.send(new genericmessage<>("#" + i)); log.info("sending message #" + i); } }; } @bean(name = outbound_id) integrationflow producer() { log.info("starting producer flow.."); return flowdefinition -> { consumer spec = (kafkaproducermessagehandlerspec.producermetadataspec metadata)-> metadata.async(true) .batchnummessages(10) .valueclasstype(string.class) .valueencoder(string::getbytes); kafkaproducermessagehandlerspec messagehandlerspec = kafka.outboundchanneladapter( props -> props.put("queue.buffering.max.ms", "15000")) .messagekey(m -> m.getheaders().get(integrationmessageheaderaccessor.sequence_number)) .addproducer(this.kafkaconfig.gettopic(), this.kafkaconfig.getbrokeraddress(), spec); flowdefinition .handle(messagehandlerspec); }; } } @configuration public static class consumerconfiguration { @autowired private kafkaconfig kafkaconfig; private log log = logfactory.getlog(getclass()); @bean integrationflow consumer() { log.info("starting consumer.."); kafkahighlevelconsumermessagesourcespec messagesourcespec = kafka.inboundchanneladapter( new zookeeperconnect(this.kafkaconfig.getzookeeperaddress())) .consumerproperties(props -> props.put("auto.offset.reset", "smallest") .put("auto.commit.interval.ms", "100")) .addconsumer("mygroup", metadata -> metadata.consumertimeout(100) .topicstreammap(m -> m.put(this.kafkaconfig.gettopic(), 1)) .maxmessages(10) .valuedecoder(string::new)); consumer endpointconfigurer = e -> e.poller(p -> p.fixeddelay(100)); return integrationflows .from(messagesourcespec, endpointconfigurer) .>>handle((payload, headers) -> { payload.entryset().foreach(e -> log.info(e.getkey() + '=' + e.getvalue())); return null; }) .get(); } } public static void main(string[] args) { springapplication.run(demoapplication.class, args); } } the example makes heavy use of java 8 lambdas. the producer spends a bit of time establishing how many messages will be sent in a single send operation, how keys and values are encoded (kafka only knows about byte[] arrays, after all) and whether messages should be sent synchronously or asynchronously. in the next line, we configure the outbound adapter itself and then define an integrationflow such that all messages get sent out via the kafka outbound adapter. the consumer spends a bit of time establishing which zookeeper instance to connect to, how many messages to receive (10) in a batch, etc. once the message batches are recieved, they’re handed to the handle method where i’ve passed in a lambda that’ll enumerate the payload’s body and print it out. nothing fancy. using apache kafka with spring xd apache kafka is a message bus and it can be very powerful when used as an integration bus. however, it really comes into its own because it’s fast enough and scalable enough that it can be used to route big-data through processing pipelines. and if you’re doing data processing, you really want spring xd ! spring xd makes it dead simple to use apache kafka (as the support is built on the apache kafka spring integration adapter!) in complex stream-processing pipelines. apache kafka is exposed as a spring xd source - where data comes from - and a sink - where data goes to. spring xd exposes a super convenient dsl for creating bash -like pipes-and-filter flows. spring xd is a centralized runtime that manages, scales, and monitors data processing jobs. it builds on top of spring integration, spring batch, spring data and spring for hadoop to be a one-stop data-processing shop. spring xd jobs read data from sources , run them through processing components that may count, filter, enrich or transform the data, and then write them to sinks. spring integration and spring xd ninja marius bogoevici , who did a lot of the recent work in the spring integration and spring xd implementation of apache kafka, put together a really nice example demonstrating how to get a full working spring xd and kafka flow working . the readme walks you through getting apache kafka, spring xd and the requisite topics all setup. the essence, however, is when you use the spring xd shell and the shell dsl to compose a stream. spring xd components are named components that are pre-configured but have lots of parameters that you can override with --.. arguments via the xd shell and dsl. (that dsl, by the way, is written by the amazing andy clement of spring expression language fame!) here’s an example that configures a stream to read data from an apache kafka source and then write the message a component called log , which is a sink. log , in this case, could be syslogd, splunk, hdfs, etc. xd> stream create kafka-source-test --definition "kafka --zkconnect=localhost:2181 --topic=event-stream | log"--deploy and that’s it! naturally, this is just a tase of spring xd, but hopefully you’ll agree the possibilities are tantalizing. deploying a kafka server with lattice and docker it’s easy to get an example kafka installation all setup using lattice , a distributed runtime that supports, among other container formats, the very popular docker image format. there’s a docker image provided by spotify that sets up a collocated zookeeper and kafka image . you can easily deploy this to a lattice cluster, as follows: ltc create --run-as-root m-kafka spotify/kafka from there, you can easily scale the apache kafka instances and even more easily still consume apache kafka from your cloud-based services. next steps you can find the code for this blog on my github account . we’ve only scratched the surface! if you want to learn more (and why wouldn’t you?), then be sure to check out marius bogoevici and dr. mark pollack’s upcoming webinar on reactive data-pipelines using spring xd and apache kafka where they’ll demonstrate how easy it can be to use rxjava, spring xd and apache kafka!
April 18, 2015
by Pieter Humphrey
· 29,134 Views
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A cluster management framework, Apache Helix
What is Helix? It is used for the automatic management of partitioned, replicated and distributed resources hosted on a cluster of nodes. Helix automates reassignment of resources in the face of node failure and recovery, cluster expansion, and reconfiguration. Modeling a distributed system as a state machine with constraints on states and transitions. Terminologies Node : A single machine Cluster: Set of Nodes Resource : A logical entry (e.g. database, index, task) Partition: Subset of the resource (Each subtask is referred to as a partition) Replica: Copy of a Partition State (e.g Master, Slave). It increase the availability of the system State: Describes the role of a replica (Each node in the cluster has its own Current State) State Machine and Transitions: An action that allows a replica to move from one state to another, thus changing its role. ( e.g Slave --> Master ) spectators: the external clients. Helix provides an External View that is an aggregated view of the current state across all nodes. Current State: represents resource's actual state at a participating node. - INSTANCE_NAME: Unique name representing the process - SESSION_ID: ID that is automatically assigned every time a process joins the cluster Rebalancer: The core component of Helix is the Controller which runs the Rebalance algorithm on every cluster event. Dynamic Ideal State: Helix powerful is that Ideal State can be changed dynamically. It is adjusting the ideal state. Whenever a cluster event occurs, Helix can operate in one of three modes FULL_AUTO SEMI_AUTO CUSTOMIZED Cluster events can be one of the following: Nodes start and/or stop Nodes experience soft and/or hard failures New nodes are added/removed [1] http://helix.apache.org/Concepts.html
April 13, 2015
by Madhuka Udantha
· 7,913 Views
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