Tag Archives: OpenStack

QEMU Advent Calendar 2016

The QEMU Advent Calendar website 2016 features a QEMU disk image each day from 01-DEC to 24 DEC. Each day a new package becomes available for download (of format tar.xz) which contains a file describing the image (readme.txt or similar), and a little run shell script that starts QEMU with the recommended command-line parameters for the disk image.

The disk images contain interesting operating systems and software that run under the QEMU emulator. Some of them are well-known or not-so-well-known operating systems, old and new, others are custom demos and neat algorithms.” [From the About section.]

This is brought to you by Thomas Huth (his initial announcement here) and yours truly.

Explore the last five days of images from the 2016 edition here! [Extract the download with, e.g. for Day 05: tar -xf.day05.tar.xz]

PS: We still have a few open slots, so please don’t hesitate to contact if you have any fun disk image(s) to contribute.

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LinuxCon talk slides: “A Practical Look at QEMU’s Block Layer Primitives”

Last week I spent time at LinuxCon (and the co-located KVM Forum) Toronto. I presented a talk on QEMU’s block layer primitives. Specifically, the QMP primitives block-commit, drive-mirror, drive-backup, and QEMU’s built-in NBD (Network Block Device) server.

Here are the slides.

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Minimal DevStack with OpenStack Neutron networking

This post discusses a way to setup minimal DevStack (OpenStack development environment from git sources) with Neutron networking, in a virtual machine.

(a) Setup minimal DevStack environment in a VM

Prepare VM, take a snapshot

Assuming you have a Linux (Fedora 21 or above or any of Debian variants) virtual machine setup (with at-least 8GB memory and 40GB of disk space), take a quick snapshot. The below creates a QCOW2 internal snapshot (that means, your disk image should be a QCOW2 image), you can invoke it live or offline:

 $ virsh snapshot-create-as devstack-vm cleanslate

So that if something goes wrong, you can revert to this clean state, by simple doing:

 $ virsh snapshot-revert devstack-vm cleanslate

Setup DevStack

There’s plenty of configuration variants to set up DevStack. The upstream documentation has its own recommendation of minimal configuration. The below configuration is of much smaller foot-print, which configures only: Nova (Compute, Scheduler, API and Conductor services), Keystone Neutron and Glance (Image service) services.

$ mkdir -p $HOME/sources/cloud
$ git clone https://git.openstack.org/openstack-dev/devstack
$ chmod go+rx $HOME
$ cat << EOF > local.conf
# To use nested KVM, un-comment the below line
# If you have `dnf` package manager, use it to improve speedups in DevStack build/tear down
export YUM=dnf

NOTE: If you’re using KVM-based virtualization under the hood, refer this upstream documentation on setting it up with DevStack, so that the VMs in your OpenStack cloud (i.e. Nova instances) can run, relatively, faster than with plain QEMU emulation. So, if you have the relevant hardware, you might want setup that before proceeding further.

Invoke the install script:

 $ ./stack.sh 

[27MAR2015 Update]: Don’t forget to systemctl enable the below services so they start on reboot — this allows you to successfully start all OpenStack services when you reboot your DevStack VM:

 $ systemctl enable openvswitch mariadb rabbitmq-server 

(b) Configure Neutron networking

Once DevStack installation completes successfully, let’s setup Neutron networking.

Set Neutron router and add security group rules

(1) Source the user tenant (‘demo’ user) credentials:

 $ . openrc demo

(2) Enumerate Neutron security group rules:

$ neutron security-group-list

(3) Create a couple of environment variables, for convenience, capturing the IDs of Neutron public, private networks and router:

$ PUB_NET=$(neutron net-list | grep public | awk '{print $2;}')
$ PRIV_NET=$(neutron net-list | grep private | awk '{print $2;}')
$ ROUTER_ID=$(neutron router-list | grep router1 | awk '{print $2;}')

(4) Set the Neutron gateway for router:

$ neutron router-gateway-set $ROUTER_ID $PUB_NET

(5) Add security group rules to enable ping and ssh:

$ neutron security-group-rule-create --protocol icmp \
    --direction ingress --remote-ip-prefix default
$ neutron security-group-rule-create --protocol tcp  \
    --port-range-min 22 --port-range-max 22 --direction ingress default

Boot a Nova instance

Source the ‘demo’ user’s Keystone credentials, add a Nova key pair, and boot an ‘m1.small’ flavored CirrOS instance:

$ . openrc demo
$ nova keypair-add oskey1 > oskey1.priv
$ chmod 600 oskey1.priv
$ nova boot --image cirros-0.3.3-x86_64-disk \
    --nic net-id=$PRIV_NET --flavor m1.small \
    --key_name oskey1 cirrvm1 --security_groups default

Create a floating IP and assign it to the Nova instance

The below sequence of commands enumerate the Nova instance, finds the Neutron port ID for a specific instance. Then, creates a floating IP, associates it to the Nova instance. Then, again, enumerates the Nova instances, so you can notice both floating and fixed IPs for it:

$ nova list
$ neutron port-list --device-id $NOVA-INSTANCE-UUID
$ neutron floatingip-create public
$ neutron floatingip-associate $FLOATING-IP-UUID $PORT-ID-OF-NOVA-INSTANCE
$ nova list

A new tenant network creation can be trivially done with a script like this.

Optionally, test the networking setup by trying to ping or ssh into the CirrOS Nova instance.

Given the procedural nature of the above, all of this can be trivially scripted to suit your needs — in fact, upstream OpenStack Infrastructure does use such automated DevStack environments to gate (as part of CI) every change that is submitted to any of the various OpenStack projects.

Finally, to find out how minimal it really is, one way to test is to check the memory footprint inside the DevStack VM, using the ps_mem tool and compare that with a Different DevStack environment with more OpenStack services enabled. Edit: A quick memory profile in a Minimal DevStack environment here — 1.3GB of memory without any Nova instances running (but, with OpenStack services running).


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Notes from a talk on “Advanced snapshots with libvirt and QEMU”

I just did a talk at a small local conference (Infrastructure.Next, co-located with cfgmgmtcamp.eu) about Advanced Snapshots in libvirt and QEMU.

Slides are here, which contains URLs to more examples.

And, some more related notes here:


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LinuxCon/KVMForum/CloudOpen Eu 2014

While the Linux Foundation’s colocated events (LinuxCon/KVMForum/CloudOpen, Plumbers and a bunch of others) are still in progress (Düsseldorf, Germany), thought I’d quickly write a note here.

Some slides and demo notes on managing snapshots/disk image chains with libvirt/QEMU. And, some additional examples with a bit of commentary. (Thanks to Eric Blake, of libvirt project, for reviewing some of the details there.)

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libvirt blockcommit: shorten disk image chain by live merging the current active disk content

When using QCOW2-based external snapshots, it is desirable to reduce an entire disk image chain to a single disk to retain performance and increase while the guest is running. Upstream QEMU and libvirt has recently acquired the ability to do that. Relevant git commits for QEMU (Jeff Cody) and libvirt (Eric Blake).

This is best illustrated with a quick example.

Let’s start with the below disk image chain as below for a guest called vm1. For simplicity’s sake:

[base] <-- [sn1] <-- [sn2] <-- [current] (live QEMU)

Once live active block commit operation is complete (step 5 below), the result will be a flattened disk image chain where data from sn1, sn2 and current are live commited into base:

 [base] (live QEMU)

(1) List the current active image in use:

$ virsh domblklist vm1
Target     Source
vda        /export/images/base.qcow2

(2) For a quick test, create external snapshots. (And, repeat the above operation two more times, so we have the chain: [base] <– [sn1] <– [sn2] <– [current] )

$ virsh snapshot-create-as \
   --domain vm1 snap1 \
   --diskspec vda,file=/export/images/sn1.qcow2 \
   --disk-only --atomic

(3) Enumerate the backing file chain:

$ qemu-img info --backing-chain current.qcow2
[. . .] # output discarded for brevity

(4) Again, check the current active disk image:

$ virsh domblklist vm1
Target     Source
vda        /export/images/current.qcow2

(5) Live Active commit an entire chain, including pivot:

$ virsh blockcommit vm1 vda \
   --active --pivot --verbose
Block Commit: [100 %]
Successfully pivoted


  • –active: It performs a two stage operation: first stage – it commits the contents from top images into base (i.e. sn1, sn2, current into base); in the second stage, the block operation remains awake to synchronize any further changes (from top images into base), here the user can take two actions: cancel the job, or pivot the job, i.e. adjust the base image as the current active image.
  • –pivot: Once data is committed from sn1, sn2 and current into base, it pivots the live QEMU to use base as the active image.
  • –verbose: Displays a progress of block operation.
  • Finally, the disk image backing chain is shortened to a single disk image.

(6) Optionally, list the current active image in use. It’s now back to ‘base’ which has all the contents from current, sn2, sn1):

$ virsh domblklist vm1
Target     Source
vda        /export/images/base.qcow2


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libvirt: default network conflicts (not anymore)

Increasingly there’s a need for libvirt networking to work inside a virtual machine that is already running on the default network ( The immediate practical case where this comes up is while testing nested virtualization: start a guest (L1) with default libvirt networking, and if you need to install libvirt again on it to run a (nested) guest (L2), there’ll be routing conflict because of the existing default route — Up until now, I tried to avoid this by creating a new libvirt network with a different IP range (or manually edit the default libvirt network).

To alleviate this routing conflict, Laine Stump (libvirt developer) now pushed a patch (with a tiny follow up) to upstream libvirt git. (Relevant libvirt bug with discussion.)

I ended up testing the patch last night, it works well.

Assuming your physical host (L0) has the default libvirt network route:

$ ip route show | grep virbr dev virbr0  proto kernel  scope link  src

Now, start a guest (L1) and when you install libvirt (which has the said fix) on it, it notices the existing route of and creates the default network on the next free network range (starting its search with, thus avoiding the routing conflict.

 $ ip route show
  default via dev ens2  proto static  metric 1024 dev ens2  proto kernel  scope link  src dev virbr0  proto kernel  scope link  src

Relevant snippet of the default libvirt network (you can notice the new network range):

  $ virsh net-dumpxml default | grep "ip address" -A4
    <ip address='' netmask=''>
        <range start='' end=''/>

So, please test it (build RPMs locally from git master or should be available in the next upstream libvirt release, early October) for your use cases and report bugs, if any.

[Update: On Fedora, this fix is available from version libvirt-1.2.8-2.fc21 onwards.]


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