Prepare A Lab For Murano

This section provides basic information about lab’s system requirements. It also contains a description of a test which you may use to check if your hardware fits the requirements. To do this, run the test and compare the results with baseline data provided.

System prerequisites

Supported Operation Systems

  • Ubuntu Server 12.04 LTS
  • RHEL/CentOS 6.4

System packages are required for Murano

Ubuntu

  • gcc
  • python-pip
  • python-dev
  • libxml2-dev
  • libxslt-dev
  • libffi-dev
  • libmysqlclient-dev
  • libpq-dev
  • python-openssl
  • mysql-client
  • python-mysqldb

CentOS

  • gcc
  • python-pip
  • python-devel
  • libxml2-devel
  • libxslt-devel
  • libffi-devel
  • postgresql-devel
  • pyOpenSSL
  • mysql
  • MySQL-python

Lab Requirements

Criteria Minimal Recommended
CPU 4 core @ 2.4 GHz 24 core @ 2.67 GHz
RAM 8 GB 24 GB or more
HDD 2 x 500 GB (7200 rpm) 4 x 500 GB (7200 rpm
RAID Software RAID-1 (use mdadm as it will improve read performance almost two times) Hardware RAID-10

Table: Hardware requirements

There are a few possible storage configurations except the shown above. All of them were tested and were working well.

  • 1x SSD 500+ GB

  • 1x HDD (7200 rpm) 500+ GB and 1x SSD 250+ GB (install the system onto

    the HDD and mount the SSD drive to folder where VM images are)

  • 1x HDD (15000 rpm) 500+ GB

Test Your Lab Host Performance

We have measured time required to boot 1 to 5 instances of Windows system simultaneously. You can use this data as the baseline to check if your system is fast enough.

You should use sysprepped images for this test, to simulate VM first boot.

Steps to reproduce test:

  1. Prepare Windows 2012 Standard (with GUI) image in QCOW2 format. Let’s assume that its name is ws-2012-std.qcow2

  2. Ensure that there is NO KVM PROCESSES on the host. To do this, run command:

    ># ps aux | grep kvm
    
  3. Make 5 copies of Windows image file:

    ># for i in $(seq 5); do \
    cp ws-2012-std.qcow2 ws-2012-std-$i.qcow2; done
    
  4. Create script start-vm.sh in the folder with .qcow2 files:

    #!/bin/bash
    [ -z $1 ] || echo "VM count not provided!"; exit 1
    for i in $(seq $1); do
    echo "Starting VM $i ..."
    kvm -m 1024 -drive file=ws-2012-std-$i.qcow2,if=virtio -net user -net nic,model=virtio -nographic -usbdevice tablet -vnc :$i & done
    
  5. Start ONE instance with command below (as root) and measure time between VM’s launch and the moment when Server Manager window appears. To view VM’s desktop, connect with VNC viewer to your host to VNC screen :1 (port 5901):

    ># ./start-vm.sh 1
    
  6. Turn VM off. You may simply kill all KVM processes by

    ># killall kvm
    

7. Start FIVE instances with command below (as root) and measure time interval between ALL VM’s launch and the moment when LAST Server Manager window appears. To view VM’s desktops, connect with VNC viewer to your host to VNC screens :1 thru :5 (ports 5901-5905):

># ./start-vm.sh 5
  1. Turn VMs off. You may simply kill all KVM processes by

    ># killall kvm
    

Baseline Data

The table below provides baseline data which we’ve got in our environment.

Avg. Time refers to the lab with recommended hardware configuration, while Max. Time refers to minimal hardware configuration.

  Boot ONE instance Boot FIVE instances
Avg. Time 3m:40s 8m
Max. Time 5m 20m

Host Optimizations

Default KVM installation could be improved to provide better performance.

The following optimizations may improve host performance up to 30%:

  • change default scheduler from CFQ to Deadline
  • use ksm
  • use vhost-net