Proj-2012-2013-OAR-Cloud

=OAR Cloud Project=

This project aims at creating a light cloud computing architecture on top of the batch scheduler OAR. The main goal is to bring the best of the cloud computing in the Grid world.

You can access to the Git repository on github.

=Project Members= This project is proposed by:

Olivier Richard - Teacher and researcher in RICM's Polytech Grenoble training

Three students from RICM are working on it:


 * Jordan Calvi (RICM4)
 * Alexandre Maurice (RICM4)
 * Michael Mercier (RICM5)

=State of the art= This project begins on January 2013. Here is the current state of the art concerning the cloud computing technologies and the underlying virtualization technologies.

Definition
The cloud computing is the use computing and storing resources through a network. It is providing a stack of services, from the hardware to the applications, named "Something as a Service". You can read a more exhaustive definition on Wikipedia.

IaaS
The layer we are interested in, is the Infrastructure as a Service layer (IaaS). It provided access to computation resources with an hardware abstraction made by virtualization. The leader in this domain is Amazon EC2. There IaaS proprietary platform is considered as the industrial standard and almost every other cloud computing solution are compatible with it's API. They provide, through a Command Line Interface (CLI) and a Web interface, a simple way to deploy scaling web applications and services. This is an on-demand self-service and you pay only when you are using it. The main features of Amazon EC2 are (from the Amazon EC2 web site): But there is lots of alternatives to Amazon. Several company provide the same kind of services using proprietary or open source solutions. You can see a comparison of some of these solutions here.
 * Select a pre-configured, templated Amazon Machine Image (AMI) to get up and running immediately. Or create an AMI containing your applications, libraries, data, and associated configuration settings.
 * Configure security and network access on your Amazon EC2 instance.
 * Choose which instance type(s) you want, then start, terminate, and monitor as many instances of your AMI as needed, using the web service APIs or the variety of management tools provided.
 * Determine whether you want to run in multiple locations, utilize static IP endpoints, or attach persistent block storage to your instances.
 * Pay only for the resources that you actually consume, like instance-hours or data transfer.

Hardware virtualization
There is a lot of system virtualization technologies. For system virtualization Amazon is using the XEN virtualization technology like most of their competitors. As we are looking for open source technologies, there is two serious alternatives to consider: KVM and LXC.


 * Xen
 * Well known and used in big mainframe cloud solution, Xen is consider as reliable. It is a bare-metal (type1) hypervisor that pivot directly on hardware. This means that every operating systems that runs on top of this hypervisor needs to be ported to fit with the paravirtualization API. It recently provide an hardware-assisted virtualization like KVM.


 * KVM
 * Included to the Linux Kernel, KVM (Kernel-based Virtual Machine) is using hardware-assisted virtualization for x86 processors with the virtualization extensions (Intel VT or AMD-V). It seems to be quite equivalent to Xen, but some say that it's quite easier to use.


 * LXC
 * The most recent one, LXC for LinuX Container use an other kind of virtualization technique based on isolation. The major drawback is that it works only for Linux OS or program. Also, the actual stable version (0.7.5) is still a work-in-progress and the API is not stabilize yet. There is lots of security issues not really solve for now . The major advantage is speed and the fact that LXC is directly accessible into the kernel.

We want to know if LXC can be a good alternative to Xen or KVM.

Libvirt is a useful tool for virtualization. It allows to use different kind of virtualization tools (above-mentioned) within a single interface. It is using XML configuration file to describe the VMs and a dedicated driver for each kind of virtualization tool.

Network virtualization
In cloud computing infrastructure we need to connect the Virtual Machines (VMs). To achieve this, the network virtualization is used. In the Linux world the most common virtual network used the virtual interface named bridge. The bridge is forwarding packet at Layer 2, so it is independent of upper layer protocols. It can be manage via the brctl command. Advanced features, like filtering or firewalling, are done using the ebtable project.

A more complete tools named OpenVSwitch is open source and commonly used in lots of cloud computing solutions. It's basically a virtual switch that can handle VMs inside a node or between multiple node over real switch.

To fit our demand regarding the network we will try to use OpenVSwitch to build our solution.

=Conception= Here is the big picture of what could be the entire solution. It aims at giving us an overview of the project and helping us to design a roadmap.

Context
There is two kind of actors that are dealing with OAR cloud, users and administrators. The F.u* and the F.a* are the user and Administrator features describe below.



User
Main features:

F.u.0 Connect to an account

F.u.1 Launch and configure one or more instances

F.u.2 Deploy an image on one or more instances

F.u.3 Modify and save images

F.u.4 Setup alarms based on rules using metrics

F.u.5 Being inform by e-mail and/or notification for interesting events

Advanced features:

F.u.6 Automated resize of an instance (adapt the resources) using predefined rules and schedule

F.u.7 Load balancing between several instances

F.u.8 Advanced Network configuration for user: ACL, subnets, VPN...

Administrator
F.a.0 Create/delete user account

F.a.1 Add/remove and manage resources

F.a.2 Visualize resources and instances states

F.a.3 Install and update nodes operating systems

F.a.4 Handle users access rights

F.a.5 Setup alarms based on rules using metrics

F.a.6 Being inform by e-mail and/or notification for interesting events

Logical Views
Here is the logical view of the OAR Cloud system. Every component on this diagram represents a software component type. The links between these components represent the communication between them.

Version 0.1
This is the first version of what could be the entire system architecture. It is design to make all the above features works.



Description of the main components:
 * AccountManager : Handle users and admins access rights
 * AccessPoint : The system access point reached by the different access tools
 * InstanceManager : Manage the creation, configuration and deletion of instances all over the severals nodes. It also handles the appliances persistence and deployment
 * UserCLI & AdminCLI : Command line access tools for users and admins

Version 0.2
Not relevant : skip it!

Version 0.3
This logical view was made after the M1 milestone and based on the knowledge gained this step. It is a much more minimal approach. However, it only complete the F.u.0 to F.u.3 and F.a.0 to F.a.4 features.



Description of the main component:
 * OARVirtCLI : It is a command line tool (CLI) that is install on the user's computer. It allows to :
 * create an instance
 * display the available images
 * run one or more images on an instance
 * connect to a running image
 * stop a running image
 * delete an instance

How it works
ssh root@IP
 * The user create an instance
 * He gets the available images from his instance
 * He launch the the chosen image
 * Then he connect himself to the image using ssh

=Milestones= This table presents the milestones of the project. Each Milestones are described below.

M1
In an Ubuntu 12.04 LTS environement
 * 1) install and configure OAR
 * 2) install and configure LXC
 * 3) make OAR reservation
 * 4) launch one or more VM using LXC
 * 5) Connect to the VM
 * 6) check if killing the job do kill the VM
 * 7) script this!

The cigri devel appliance was used as an configuration example for this. The Ubuntu 12.04 LTS distribution has been chosen because it seems to be one of the few distributions where LXC works out-of-the-box.

OAR settings

 * the job manager "job_resource_manager_cgroups.pl" generate cpuset errors
 * the job manager "job_resource_manager.pl" generate cpuset errors too
 * I thought the problem come from a database conflict so I tried to use
 * I tried to run the `update_cpuset_id.sh` script but it shows an error message either:

The problem comes from the cgroup-lite service that run by default in an Ubuntu 12.04. Stop this service using service cgroup-lite stop solve the problem for OAR but puts LXC down.

I find a trick to make OAR and LXC working together: I disable the cpuset feature of OAR. In the /etc/oar/oar.conf (there is a copy in the M1 folder) I have comment CPUSET_PATH and set to yes OARSUB_FORCE_JOB_KEY as it is provided in the CPUSET_PATH comment.

Thus, I could run an LXC container inside a job. The container was vanished when the job has been killed.

Questions

 * Is the OAR cpuset mandatory, even if the LXC manage it?
 * Is LXC mature enough to use it in production?

M1 Conclusion
During this milestone we learned several things:
 * libvirt uses a separate implementation of LXC and not the LXC package itself. Also, it can be harder to use and cuts some LXC functionalities like reboot and shutdown a container.
 * by default OAR and LXC (like it works on Ubuntu 12.04) are in conflict because of the use of cgroups by OAR. The current default mount point of cgroups with LXC use /sys/fs/cgroup/. Each subsystems (cpuset, cpuacct, memory,...) is mount separately on /sys/fs/cgroup/ where  is one of the subsystem name. It seems that rewriting the cgroups management part of the job_resource_manager_cgroups.pl file, to fit with the cgroups mount points, should eventually makes them works together. After some try, we found out that oarsh and oarsh_shell should be modify too as it is said in the documentation but the functions to modify does not exists. However it might be possible to configure OAR and to works with LXC if we dig deeper.
 * The LXC security is not efficient by default. Some distribution are using SELinux to secure the container but OAR is not working with SELinux. Even so, there is several ways to make a container secure using AppArmor or systemd with a sandbox.
 * LXC is quite a young project and it's not stabilized for now. The documentation is a bit poor and makes LXC works depends on a lots of parameters. Moreover, depending on the Linux distribution the LXC configuration is totally different. It makes this tool really hard to understand and configure.

We can notice that systemd-nspawn, a kind of container launcher based on systemd. It is currently just a hack tool but it might become an LXC alternative for systemd based distributions.

M2
In Ubuntu 12.04 LTS
 * 1) install and configure LXC, libvirt and OpenVswitch
 * 2) launch at least 2 VMs
 * 3) make the VMs to ping each others
 * 4) script this!

M3
TODO

=Tools=

LXC
LXC is a lightweight hypervisor allowing to run isolated appliances. Indeed, it provides a virtual environment that has its own process and network space. It is similar to a chroot. As LXC is implemented on given linux kernel, only operating systems that are compatible with the hosting kernel will be able to run. It is based on cgroups (control groups), a Linux kernel feature to manage ressources like CPU, memory and disk I/O by limiting resources, prioritizing groups, accounting (measuring), isolating (separate namespaces for groups, it means processes, network connections and files are not visible by other groups) and controling groups.

Installation
/!\ LXC as been set up succesfully on ubuntu 12.04 LTS as container launching does not works on Debian Wheeze testing OS. /!\

Packages installation
 * /?\ Conteners will be placed in /var/lib/lxc /?\
 * /?\ Conteners will be placed in /var/lib/lxc /?\

''Mounting cgroups automatically : edit /etc/fstab and add the following

''Enabling previous modifications

''Checking everything is ok

Manipulation of containers
''Creating a container running Ubuntu
 * /!\ By default, the version of the guest OS is the same as the hosting one. /!\
 * /!\ By default, the version of the guest OS is the same as the hosting one. /!\

''Showing existing containers and thoses that are running
 * /?\ The first line indicates existing containers and the second one thoses in running state. /?\
 * /?\ The first line indicates existing containers and the second one thoses in running state. /?\

''Obtaining information about ubuntu1

''Starting the container

''Connection to the container

''Shutting down the container

''Exiting console
 * perform

Deleting the container

Configuring the container
At boot time, a virtual machines reads the file /var/lib/lxc/{VM-name}/config to set up its configuration (root file system, number of TTY, limites, etc).  lxc.network.type=veth lxc.network.link=lxcbr0 lxc.network.flags=up lxc.network.hwaddr = 00:16:3e:24:e5:9a lxc.utsname = ubuntu1

lxc.devttydir = lxc lxc.tty = 4 lxc.pts = 1024 lxc.rootfs = /var/lib/lxc/ubuntu1/rootfs lxc.mount = /var/lib/lxc/ubuntu1/fstab lxc.arch = amd64 lxc.cap.drop = sys_module mac_admin lxc.pivotdir = lxc_putold


 * 1) uncomment the next line to run the container unconfined:
 * 2) lxc.aa_profile = unconfined

lxc.cgroup.devices.deny = a lxc.cgroup.devices.allow = c *:* m lxc.cgroup.devices.allow = b *:* m lxc.cgroup.devices.allow = c 1:3 rwm lxc.cgroup.devices.allow = c 1:5 rwm lxc.cgroup.devices.allow = c 5:1 rwm lxc.cgroup.devices.allow = c 5:0 rwm lxc.cgroup.devices.allow = c 1:9 rwm lxc.cgroup.devices.allow = c 1:8 rwm lxc.cgroup.devices.allow = c 136:* rwm lxc.cgroup.devices.allow = c 5:2 rwm lxc.cgroup.devices.allow = c 254:0 rwm lxc.cgroup.devices.allow = c 10:229 rwm lxc.cgroup.devices.allow = c 10:200 rwm lxc.cgroup.devices.allow = c 1:7 rwm lxc.cgroup.devices.allow = c 10:228 rwm lxc.cgroup.devices.allow = c 10:232 rwm 
 * 1) Allow any mknod (but not using the node)
 * 1) /dev/null and zero
 * 1) consoles
 * 1) lxc.cgroup.devices.allow = c 4:0 rwm
 * 2) lxc.cgroup.devices.allow = c 4:1 rwm
 * 3) /dev/{,u}random
 * 1) rtc
 * 1) fuse
 * tun
 * 1) full
 * 1) hpet
 * kvm

Configuring default network and switch
see: /etc/default/lxc

Installation
Packages installation

Creating an XML file configuration to import an existing container in libvirt
 * /!\ Notice that libvirt can not install am OS in a container. Therefore, an LXC container with an OS must have been set up previously (that was the we saw before). Then, the file system directory will be given to libvirt when importing the VM. /!\

  ubuntu1 332768   exe /sbin/init  1   destroy restart destroy /usr/lib/libvirt/libvirt_lxc 
 * In order to create a libvirt container, an XML file describing the VM we want to import must be filled. There is a sample of such an XML file that belong to VM "ubuntu1" we have just created :

Booting the container

Connecting to the container localy

Connecting to the container remotly

Shutting the container 

Deleting the container

Problemes

 * Using Ubuntu as a host,when connecting to a libvirt VM running Debian, the guest appliance waits for the user to log in through two interfaces at a time (tty1 and console), so it is not possible to get identified.


 * Using Debian Wheeze as a host, when connecting to a libvirt VM, the console does not offer the user the possibility to log in. However, when using directly LXC there is no issue.

Internal links

 * UML

12/03

 * add 0.3 version  in conception part

11/03

 * begin of M2

09/03

 * add State of the art part

08/03

 * M1 is closed. OAR cpuset and LXC does not work in competition in the same node (see why)

22/02

 * M1 works in simple mode (OAR does not use cpuset)

19/02

 * milestone definitions

07/02

 * add Conception part

04/02

 * We have specified the subject
 * Distribute the work between us.
 * Jordan: LXC and Libvirt
 * Alexandre: OpenVSwitch and Libvirt
 * Michael: OAR and global architecture