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Cloud Native Application

This document purpose is to describe the Cloud Native Application training described below and which is in particular delivered to ENSIMAG IS students in 2017 and 2018.

Document writers:

Overview of the Assessment

Objectives

The goal of this document is to describe the use case that will be used for the training of ENSIMAG students

Reference documents

The main OpenStack entry point is at http://www.openstack.org

  • v1.0: 2016-09-29 - First version
  • v1.1: 2016-11-28 - Update with grade per part
  • v1.2: 2017-01-16 - Update with evaluation method
  • v2.0: 2017-09-25 - More focus on the DevOps life-cycle
  • v2.1: 2017-10-20 - Review to match 2017 expectations

Project Story

You are in a company which achieved an aggressive deal with a Customer to leverage an open source cloud native application and use it internally for their customers.

With a new team, you are in charge to deliver and maintain the application in production in your new customer environment.

The customer gave you 4 major objectives:

  • The application is an open source cloud native application: lottery for an e-commerce site
  • The customer requires the production environment to be Openstack cloud based. The customer won't install or maintain it. This will be one of your tasks.
  • Any feature/bug request must be in production quickly, with control & quality.
  • You will have 7 weeks to deliver the application on the customer Hardware. Before that date, the environment won't be considered as production and can be re-built from scratch, anytime. Just contact the customer to do it.

The Customer will give you 2 servers pre-installed with CentOS 7, to deliver the application in production.

Your company gives you an access to a reference OpenStack setup hosting a tenant to develop your environment (factory).

Objectives

The goal of this training is to build a software factory to do:

  • Continuous Improvement
  • Continuous Testing
  • Continuous Integration
  • Continuous Deployment of a cloud native application

Co-related goals are:

  • Ensure security
  • Improve team work

Goals & constraints

Goals

To answer to customer need, your team choose to use the DevOps method/approach/best practices to deploy and maintain this application in production in the customer company HW.

As a consequence, practitioners will first have to:

  • Organize the team to work using DevOps best practices.
  • Automate the management of a virtual infrastructure (Infrastructure as code concept). Your customer requires the use/usage of Openstack as an Infrastructure as a Service platform (IaaS)
  • Define and implement a CICD pipeline to easily test and deploy the application to a staging area then to production.
  • Put in place tooling to share/track application changes between team members/customers.
  • Ensure correct level of security within the factory. (no private keys or data available publicly, user access restriction, ports filtering...)

Constraints

  • Application should only expose http[s] (ports 80 and 443) to the external network.
  • All materials should be kept on public git repository (github, gitlab, framasoft e.g.) with an Open Source license (Cf: https://opensource.org/licenses prefer the popular ones). Please note that your git history should reflect changes to the factory/infrastructure/application. Also, you should commit properly with your personal credentials (email preferred) with a unique account.
  • There is no restriction regarding the tools to implement the pipeline. It could be external services and/or on premise tools. However, be prepared to justify some choices.

Bonus goals

  • Put in place monitoring to ensure applications are working as expected.
  • Put in place name resolution.
  • Improve applications.
  • Optimize testing duration.
  • Communication dashboard about applications health to users.
  • Performance improvement of your application by scaling services.
  • Applications reliability.
  • Contribute back to the Open Source project

Application information

Application schema

application schema

Application description

  • 1 Web + reverse proxy provides a page with 5 visible parts/micro-services: I, S, B, W and P.
  • I(dentification) service: receives http request from customer (link with customer ID) and look for it into DB.
  • S(tatus) service: detect whether customer already played or not, status stored in the DB.
  • B(utton) service: button widget allowing the customer to play. Only when not already done.
  • W(orker) service that computes whether the customer won or not, called by B. If won, post an image representing what has been won into OpenStack Swift or Redis with customer ID. Then post by e-mail via an external provider a message to admins using a message bus. This service is povided by a 3rd party, so it can not be changed. As this service is really slow, scaling it should be considered.
  • P(icture) service: Look into Swift or Redis with customer ID to display the image of the customer, empty if no image.
  • Redis or Swift can be used to store data.
  • Rabbitmq is used to pass message from service B to service W1 and W2.
  • W1 services that listen on the messaging bus and write to the database.
  • W2 services that listen on the messaging bus and send http requests to mailgun external services.

Application materials (code, doc etc...)

Here is the url of the Open Source project: https://github.com/uggla/cloud_native_app

Deliverables

  • On Github:

    • Pipeline design documents and code
    • Application code
    • Infrastructure code (Heat template/ansible playbooks/scripts).
  • Your software factory should be ready to deliver a patch or a feature requested by your customer. This delivery will be in production during the exam. The feature or fix requested can come from the upstream Open Source project.

  • As a backup, a video that will present the CICD of the application in a new empty tenant and a customer patch to show the factory end to end.

Note: A complex feature or bug fix could be delivered several times, improving the application between each delivery. Your customer does not require this to be delivered just once. They prefer to see changes frequently. But the overall application service must not be impacted by such update.

In the context of this training, no complex feature or bug fix will be requested by your teachers.

Another Note: github is mandatory for the delivery. However, you can use any other scm solutions to meet your needs. But you must update regularly the github repo with history

Teachers interaction with students

Platforms

Teachers will provide a remote access (though VPN) to :

  • the customer production platform (known as Production environment) (2 servers pre-installed with a CentOS 7 distribution)

    Your development team will have to setup them with (packstack)[https://www.rdoproject.org/install/packstack/.

    Your development team will deploy the customer application and application health control on it.

  • a runnable company Openstack tenant (known as Reference environment) to install your software factory. In this factory, you will be able to

    • develop anything requested by your customers, or proposed by your team for improvement/bug fix.
    • test your application and his delivery
    • control the application and software factory health

Roles

Your teachers will take and behave with 2 different roles:

When you contact your customer or your company, remind your group number.

Training support

Outside of these roles that your teachers will have, you can get support on the overall training subject, by mail or during the different sessions, to:

  • Ask question,
  • Get help (VPN Access, platform setup, expertise)
  • Discuss

The mailing list is: ensimag-internal@lists.osp.hpe.com

Agenda

Each session is 3 hours long

First session

  • Project explanation: Overall Goals & method (groups, prod platform, TD systems for tests). No formal solution will be directly given, students will have to build the solution by themselves. Many approaches are possible. The teachers team role will be after the 2 first sessions and generic presentations on all concepts to help them in the realization of that application and its setup. (Christophe / René)
  • OpenStack architecture & example (Bruno)
  • Docker (Bruno)
  • Company Openstack tenant (known as Reference Environment) platform explanation (Vincent)
  • OpenVPN setup
  • Waystation creation (see below) --> pb need group defined.
  • Home work:
    • Continue to explore OpenStack from both UI & CLI
    • Explore tools to use for the factory and automation systems
    • Create 9 groups of 5 students (one country per group), assign specialization (ops, devs, middleware, ... + backup), tool choice left to students, but licensing should be correct (prefer Open Source)

Second session

  • DevOps fundamentals (Christophe)
  • Application overview (René)
  • Infrastructure as Code: OpenStack API as TD
  • Project explanation: Architecture of the use case - Specifications - Design Constraints & Goals (GitHub, automation, )
  • Home work: Continue to explore OpenStack API (Dev), DevOps concept and tools, Start Prod Infra setup

Third session

  • Team member role and responsibility. Assigning tasks... Who does what? The customer like to see that...
  • Design and implement a flow to develop and deliver application architecture
  • Prod infra setup continued: Ability to launch a VM from an image using a heat template, attached to a network and a storage, and an object storage. private and public net are available and a floating IP attached to the VM.
  • Application architecture done: microservices identified, HA solved, Scalability solved. Design done (Paper work, UML ?).

Fourth session

  • Prod infra setup finished: Ability to launch a VM from an image using a heat template, attached to a network and a storage, and an object storage. private and public net are available and a floating IP attached to the VM.
  • Application architecture development ongoing
  • Factory improvement to deliver fisrt version of the application ecosystem

Fifth session

  • Prod infra setup / factory review if needed
  • Application ecosystem and software factory improved to deliver more.

Sixth session

  • Application ecosystem continuous improvement.

Seventh session

  • Synthesis and integration
  • Group Presentation
  • Integrate a customer request (feature or bug fix) in the factory

Eigth session

  • Evaluation of the projects

Evaluation

Evaluation will be 25' Maximum per group including 5' for Q&A. You will present :

  • application ecosystem architecture
  • factory architecture
  • your roles,
  • tasks done,
  • code, commits,
  • Factory flow from development to deployment
  • Process used and description (how you work together)

Then, the functional evaluation will be done on architecture with explanation of choices, methods and tools used.

  • Reminder: Plan to have a backup video.
  • A presentation to explain the major steps and choices might be useful, but not mandatory

Send all deliverable planned in advance of the evaluation (before 7th session) to allow time for teachers to look at them. Think to provide access if your project is not public.

Points Topic to evaluate
5 Dev team
  • On Gihub:
    • Automation code to test and deploy
    • Performance and tests results
    • Application code
  • Application design document
  • Present the automatic deployment of the application in a tenant and make reliability checks.
5 Factory (Ops) team
  • Available
  • Operational
  • With the mandatory components (Agile/CI/CD/...)
  • And optional ones needed by the development teams
  • On Gihub:
    • Heat templates/ansible playbooks/scripts for Infra group
5 Production services
  • Production IaaS up and running based en packstack
  • Application still working, independently
    Support for failure and scalability
  • Self healing
  • Monitoring
5 Project life
  • Improvement/bug fix timeline from dev to prod
  • Agile project plan
  • ChatOps, Issue tracking, support
  • Upstream relationship

How to create your bastion vm on Reference environment

Connection :

  1. Connect using OpenVPN. The lab network uses
  • HPE Blades, for the production environment
  • HPE Moonshot cartridges, for the staging environment

all are located in the HPE Customer Innovation Center and reached through a dedicated VPN.

Each students group will receive a Lab number (X) from the instructors team

All students servers receive their fixed-assigned addresses using a DHCP server. In order to connect to them, a VPN is provided. You need to activate that VPN by launching on Linux the following commands:

WARNING!! The FTP service will be opened ONLY during the session 1.

Keep your keys somewhere else.

$ mkdir -p ~/lab
$ cd ~/lab
$ wget ftp://ftp.hpecic.net/pub/openvpn/ca.crt
$ wget ftp://ftp.hpecic.net/pub/openvpn/lab2017.key
$ wget ftp://ftp.hpecic.net/pub/openvpn/lab2017.crt
$ wget ftp://ftp.hpecic.net/pub/openvpn/vpnlab2017.conf
$ sudo openvpn --config vpnlab2017.conf

For those of you unlucky using a Windows desktop system, then install first wget from http://labossi.hpintelco.net/win/wget.exe or http://labossi.hpintelco.net/win/wget64.exe and then openvpn in case you don't have it from http://openvpn.net/index.php/open-source/downloads.html (internal mirror at http://labossi.hpintelco.net/win/)

You need to launch a cmd command as Administrator on your system (use the Start/windows button, type cmd and right click on the icon appearing to select Run as Administrator) and then you have to run in it

C:\WINDOWS\SYSTEM32> md C:\openvpn
C:\WINDOWS\SYSTEM32> cd C:\openvpn

Download the 4 files previously mentioned in the wget command under C:\openvpn. Then issue:

C:\openvpn> openvpn --config vpnlab2017.conf

For those of you unlucky using a MacOS desktop system, then install a compatible openvpn tool in case you don't have it already from https://code.google.com/p/tunnelblick/. Then launch TunnelBlick using that conf file.

From now on, you should be able to connect using ssh to the systems.

For those of you still unlucky using a Windows desktop system, then install putty in case you don't have it from http://www.chiark.greenend.org.uk/~sgtatham/putty/download.html.

Then launch putty in the run command interface and log on your target system.

  1. Connect to the Openstack Dashboard. Reference OpenStack dashboard IP:
  2. To log use : http://10.11.50.7/
    • user name : LabX (X = number of your group)
    • password : The password for your group that you should have received by mail.

At that step, you shoud be connected in your respective tenant (groupeX) with a fresh environment. You need to create a minimal infrastructure, a bastion server using the dashboard.

This openstack has a lot more services than the one we used in the first session. (note that swift and cinder are not yet available which is a problem only for service P and B) The neutron network service is available, and you will have to use it to create your networks that will host the bastion server.

Create a private network:

  1. Open the menu and click on network then choose networks subitem.
  2. Create a new network.
    • Name : you can use whatever name, but as an example we will use "private"
    • Subnet name : private_subnet
    • Network address : CIDR of your network, you can choose what you want, here as an example we can use 192.168.5.0/24.
    • Gateway IP : by default it will use the first IP of the range
    • In subnet details just provide the DNS : 10.3.156.12

This will be your private network, we will deploy our admin VMs inside that network. You can see there is another network called external-network. This network is a public one. It will be used to provide access to VM from the outside by mapping a floating ip. However before that, we need to connect private network and external network with a router.

Create a router:

  1. Open the menu and click on network then choose routers subitem.
  2. Create a router
    • Name : router1 (as an example)
    • External network : public
  3. Click on the router1 just created and add an interface to the private network.
  4. You can verify in "Network Topology" that you have a router in beetween external network and internal one.

Now the networking should be in place.

Create your bastion (admin) server and access it :

  1. Deploy a new vm via the dashboard (launch a new instance)

    • Name: bastion
    • Image: Fedora or Ubuntu (the one you prefer, they have both recent openstack tools)
    • Flavor: v1.m1.d5
    • Network: private1 (not the external)
    • Security group: default
    • Key pair: Generate your keypair or provide your ssh pub key.
  2. Associate a floating ip to your server (via network --> Accès & Sécurité --> IP flottantes) This is a bit tricky, you need first to allocate a floating ip (this will give you an IP on the external network) Then you will associate this external ip to your bastion VM on the private network.

Ex : in the instance dashboard you should see in the IP column : VM name :bastion

192.168.5.5

Floating IPs:

10.11.53.15
  1. Open the menu and click on compute then choose access and security subitem.

  2. Manage the default security group to allow Ingress ssh(port 22)

  3. You should be able to log on your vm using the floating ip and the ssh key created before. (please ask if you need assistance with ssh) Ex: ssh fedora@10.11.53.15 or ssh ubuntu@10.11.53.15

  4. You can install the openstack client to manage the API and do automation. (assuming there is no errors in the above parts) Ex: dnf install python-openstackclient --> this will install a recent version of the openstack client on Fedora

  5. Get your openrc files by opening the menu and click on compute then choose access and security subitem and menu API access. Here you can download a rcfile that will give you all the settings to connect to your environment. You just need to source that file to export the OS* required environment variables.

Note : Consider the default security group as your admin subnet. Restrict access to it to only ssh. Applications should be deployed in their respective networks and corresponding security groups.

Advice 1 : do not create a lot of security groups, you will become crazy managing them. A good approach is to map a security group per network and open the required ports.

Advice 2 : look at the orchestration part and mostly service heat. Sounds like an easy way to deploy stuff although not mandatory.

Advice 3 : using IP is painfull in a cloud environment, prefer names.

Production environment

Each group will have 2 servers pre-installed with a CentOS 7 distribution. Your development team will have to setup them with packstack: https://www.rdoproject.org/install/packstack/.

Image

Servers and External IP assigments

Lab ID IP Server 1 IP Server 2 FIP DHCP start FIP DHCP end
Lab 1 10.11.51.138 10.11.51.174 10.11.54.10 10.11.54.29
Lab 2 10.11.51.140 10.11.51.141 10.11.54.30 10.11.54.49
Lab 3 10.11.51.142 10.11.51.143 10.11.54.50 10.11.54.69
Lab 4 10.11.51.144 10.11.51.145 10.11.54.70 10.11.54.89
Lab 5 10.11.51.161 10.11.51.162 10.11.54.90 10.11.54.109
Lab 6 10.11.51.163 10.11.51.164 10.11.54.110 10.11.54.129
Lab 7 10.11.51.165 10.11.51.159 10.11.54.130 10.11.54.149
Lab 8 10.11.51.167 10.11.51.173 10.11.54.150 10.11.54.169
Lab 9 10.11.51.169 10.11.51.170 10.11.54.170 10.11.54.189
Lab 10 10.11.51.171 10.11.51.172 10.11.54.190 10.11.54.209

Tips for PackStack deployment

  • Update your servers

  • Install packstack packages (step 0 to step 2)

  • Generate and update an answer file: packstack --gen-answer-file=ensimag-packstack.txt
    CONFIG_NTP_SERVERS=10.3.252.26
    CONFIG_NEUTRON_ML2_TYPE_DRIVERS=vxlan,flat,vlan
    CONFIG_NEUTRON_ML2_FLAT_NETWORKS=extnet
    CONFIG_NEUTRON_ML2_VLAN_RANGES=extnet:2232:2232
    CONFIG_NEUTRON_OVS_BRIDGE_IFACES=br-ex:eno1
    CONFIG_NEUTRON_OVS_BRIDGES_COMPUTE=br-ex
    CONFIG_PROVISION_DEMO=n

  • Deploy your packstack : packstack --answer-file=ensimag-packstack.txt

  • If your deployment is successful, try to access your OpenStack via Horizon

  • Connect with the external network:
    Source your rc file.
    Create network: neutron net-create public --router:external --provider:network_type vlan
    --provider:physical_network extnet --provider:segmentation_id 2232
    Create subnet: neutron subnet-create --name public-subnet --enable_dhcp=False
    --allocation-pool=start=10.11.54.X,end=10.11.54.Y --gateway=10.11.54.1 public 10.11.54.1/24