Planet RDO

OS Migrate is a toolbox for content migration (workloads and more) between OpenStack clouds. Let’s dive into why you’d use it, some of its most notable features, and a bit of how it works.

The Why

Why move cloud content between OpenStacks? Imagine these situations:

• Old cloud hardware is obsolete, you’re buying new. A new green field deployment will be easier than gradual replacement of hardware in the original cloud.

• You want to make fundamental changes to your OpenStack deployment, that would be difficult or risky to perform on a cloud which is already providing service to users.

• You want to upgrade to a new release of OpenStack, but you want to cut down on associated cloud-wide risk, or you can’t schedule cloud-wide control plane downtime.

• You want to upgrade to a new release of OpenStack, but the cloud users should be given a choice when to stop using the old release and start using the new.

• A combination of the above.

In such situations, running (at least) two clouds in parallel for a period of time is often the preferable path. And when you run parallel clouds, perhaps with the intention of decomissioning some of them eventually, a tool may come in handy to copy/migrate the content that users have created (virtual networks, routers, security groups, machines, block storage, images etc.) from one cloud to another. This is what OS Migrate is for.

The Pitch

Now we know OS Migrate copies/moves content from one OpenStack to another. But there is more to say. Some of the design decisions that went into OS Migrate should make it a tool of choice:

• Uses standard OpenStack APIs. You don’t need to install any plugins into your clouds before using OS Migrate, and OS Migrate does not need access to the backends of your cloud (databases etc.).

• Runnable with tenant privileges. For moving tenant-owned content, OS Migrate only needs tenant credentials (not administrative credentials). This naturally reduces risks associated with the migration.

  If desired, cloud tenants can even use OS Migrate on their own. Cloud admins do not necessarily need to get involved.

  Admin credentials are only needed when the content being migrated requires admin privileges to be created (e.g. public Glance images).

• Transparent. The metadata of exported content is in human-readable YAML files. You can inspect what has been exported from the source cloud, and tweak it if necessary, before executing the import into the destination cloud.

• Stateless. There is no database in OS Migrate that could get out of sync with reality. The source of migration information are the human readable YAML files. ID-to-ID mappings are not kept, entry-point resources are referred to by names.

• Idempotent. In case of an issue, fix the root cause and re-run, be it export or import. OS Migrate has mechanisms against duplicit exports and duplicit imports.

• Cherry-pickable. There’s no need to migrate all content with OS Migrate. Only migrate some tenants, or further scope to some of their resource types, or further limit the resource type exports/imports by a list of resource names or regular expression patterns. Use as much or as little of OS Migrate as you need.

• Implemented as an Ansible collection. When learning to work with OS Migrate, most importantly you’ll be learning to work with Ansible, an automation tool used across the IT industry. If you already know Ansible, you’ll feel right at home with OS Migrate.

The How

If you want to use OS Migrate, the best thing I can do here is point towards the OS Migrate User Documentation. If you just want to get a glimpse for now, read on.

As OS Migrate is an Ansible collection, the main mode of use is setting Ansible variables and running playbooks shipped with the collection.

Should the default playbooks not fit a particular use case, a technically savvy user could also utilize the collection’s roles and modules as building blocks to craft their own playbooks. However, as i’ve wrote above in the point about cherry-picking features, we’ve tried to make the default playbooks quite generically usable.

In OS Migrate we differentiate between two main migration types with respect to what resources we are migrating: pre-workload migration, and workload migration.

Pre-workload migration

Pre-workload migration focuses on content/resources that can be copied to the destination cloud without affecting workloads in the source cloud. It can be typically done with little timing pressure, ahead of time before migrating workloads. This includes resources like tenant networks, subnets, routers, images, security groups etc.

The content is serialized as editable YAML files to the Migrator host (the machine running the Ansible playbooks), and then resources are created in the destination according to the YAML serializations.

Workload migration

Workload migration focuses on copying VMs and their attached Cinder volumes, and on creating floating IPs for VMs in the destination cloud. The VM migration between clouds is a “cold” migration. VMs first need to be stopped and then they are copied.

With regards to the boot disk of the VM, we support two options: either the destination VM’s boot disk is created from a Glance image, or the source VM’s boot disk snapshot is copied into the destination cloud as a Cinder volume and the destination VM is created as boot-from-volume. There is a migration parameter controlling this behavior on a per-VM basis. Additional Cinder volumes attached to the source VM are copied.

The data path for VMs and volumes is slightly different than in the pre-workload migration. Only metadata gets exported onto the Migrator host. For moving the binary data, special VMs called conversion hosts are deployed, one in the source and one in the destination. This is done for performance reasons, to allow the VMs’ and volumes’ binary data to travel directly from cloud to cloud without going through the (perhaps external) Migrator host as an intermediary.

The Pointers

Now that we have an overview of OS Migrate, let’s finish with some links where more info can be found:

• OS Migrate Documentation is the primary source of information on OS Migrate.

• OS Migrate Matrix Channel is monitored by devs for any questions you might have.

• Issues on Github is the right place to report any bugs, and you can ask questions there too.

• If you want to contribute (code, docs, …), see OS Migrate Developer Documentation.

Have a good day!

RDO Wallaby Released

• With the Victoria release, source tarballs are validated using the upstream GPG signature. This certifies that the source is identical to what is released upstream and ensures the integrity of the packaged source code.
• With the Victoria release, openvswitch/ovn are not shipped as part of RDO. Instead RDO relies on builds from the CentOS NFV SIG.
• Some new packages have been added to RDO during the Victoria release:
  • RBAC supported added in multiple projects including Designate, Glance, Horizon, Ironic, and Octavia
  • Glance added support for distributed image import
  • Ironic added deployment and cleaning enhancements including UEFI Partition Image handling, NVMe Secure Erase, per-instance deployment driver interface overrides, deploy time “deploy_steps”, and file injection.
  • Kuryr added nested mode with node VMs running in multiple subnets is now available. To use that functionality a new option [pod_vif_nested]worker_nodes_subnets is introduced accepting multiple Subnet IDs.
  • Manila added the ability for Operators to now set maximum and minimum share sizes as extra specifications on share types.
  • Neutron added a new subnet type network:routed is now available. IPs on this subnet type can be advertised with BGP over a provider network.
  • TripleO moved network and network port creation out of the Heat stack and into the baremetal provisioning workflow.

Other highlights of the broader upstream OpenStack project may be read via https://releases.openstack.org/wallaby/highlights.html

Contributors

• Adriano Petrich
• Alex Schultz
• Alfredo Moralejo
• Amol Kahat
• Amy Marrich
• Ananya Banerjee
• Artom Lifshitz
• Arx Cruz
• Attila Fazekas
• Bhagyashri Shewale
• Brian Haley
• Cédric Jeanneret
• Chandan Kumar
• Daniel Pawlik
• David J Peacock
• Dmitry Tantsur
• Emilien Macchi
• Eric Harney
• Fabien Boucher
• Gabriele Cerami
• Gael Chamoulaud
• Grzegorz Grasza
• Harald Jensas
• Jason Joyce
• Javier Pena
• Jeremy Freudberg
• Jiri Podivin
• Joel Capitao
• Kevin Carter
• Luigi Toscano
• Marc Dequenes
• Marios Andreou
• Martin Kopec
• Mathieu Bultel
• Matthias Runge
• Mike Turek
• Nicolas Hicher
• Pete Zaitcev
• Pooja Jadhav
• Rabi Mishra
• Riccardo Pittau
• Roman Gorshunov
• Ronelle Landy
• Sagi Shnaidman
• Sandeep Yadav
• Slawek Kaplonski
• Sorin Sbarnea
• Steve Baker
• Takashi Kajinami
• Tristan Cacqueray
• Waleed Mousa
• Wes Hayutin
• Yatin Karel

The Next Release Cycle

At the end of one release, focus shifts immediately to the next release i.e Xena.

Get Started

There are three ways to get started with RDO.

To spin up a proof of concept cloud, quickly, and on limited hardware, try an All-In-One Packstack installation. You can run RDO on a single node to get a feel for how it works.

For a production deployment of RDO, use TripleO and you’ll be running a production cloud in short order.

Finally, for those that don’t have any hardware or physical resources, there’s the OpenStack Global Passport Program. This is a collaborative effort between OpenStack public cloud providers to let you experience the freedom, performance and interoperability of open source infrastructure. You can quickly and easily gain access to OpenStack infrastructure via trial programs from participating OpenStack public cloud providers around the world.

Get Help

The RDO Project has our users@lists.rdoproject.org for RDO-specific users and operators. For more developer-oriented content we recommend joining the dev@lists.rdoproject.org mailing list. Remember to post a brief introduction about yourself and your RDO story. The mailing lists archives are all available at https://mail.rdoproject.org. You can also find extensive documentation on RDOproject.org.

The #rdo channel on Freenode IRC is also an excellent place to find and give help.

We also welcome comments and requests on the CentOS devel mailing list and the CentOS and TripleO IRC channels (#centos, #centos-devel, and #tripleo on irc.freenode.net), however we have a more focused audience within the RDO venues.

Get Involved

To get involved in the OpenStack RPM packaging effort, check out the RDO contribute pages, peruse the CentOS Cloud SIG page, and inhale the RDO packaging documentation.

Join us in #rdo and #tripleo on the Freenode IRC network and follow us on Twitter @RDOCommunity. You can also find us on Facebook and YouTube.

collectd itself is intended as lightweight collecting agent for metrics and events. In larger infrastructure, the data is sent over the network to a central point, where data is stored and processed further.

This introduces a potential issue: what happens, if the remote endpoint to write data to is not available. The traditional network plugin uses UDP, which is by definition unreliable.

Collectd has a queue of values to be written to an output plugin, such was write_http or amqp1. At the time, when metrics should be written, collectd iterates on that queue and tries to write this data to the endpoint. If writing was successful, the data is removed from the queue. The little word if also hints, there is a chance that data doesn't get removed. The question is: what happens, or what should be done?

There is no easy answer to this. Some people tend to ignore missed metrics, some don't. The way to address this is to cap the queue at a given length and to remove oldest data when new comes in. The parameters are WriteQueueLimitHigh and WriteQueueLimitLow. If they are unset, the queue is not limited and will grow until memory is out. For predictability reasons, you should set these two values to the same number. To get the right value for this parameter, it would require a bit of experimentation. If values are dropped, one would see that in the log file.

When collectd is configured as part of Red Hat OpenStack Platform, the following config snippet can be used:

parameter_defaults:
    ExtraConfig:
      collectd::write_queue_limit_high: 100
      collectd::write_queue_limit_low: 100

Another parameter can be used to limit explicitly the queue length in case the amqp1 plugin is used for sending out data: the SendQueueLimit parameter, which is used for the same purpose, but can differ from the global WriteQueueLimitHigh and WriteQueueLimitLow.

parameter_defaults:
    ExtraConfig:
        collectd::plugin::amqp1::send_queue_limit: 50

In almost all cases, the issue of collectd using much memory could be tracked down to a write endpoint not being available, dropping data occasionally, etc.

What changed with CentOS?

What’s the current situation in RDO?

What’s our plan for RDO roadmap?

• RDO Wallaby (ETA is end of April 2021) will be built, tested and released only on CentOS 8 Stream.
• RDO CloudSIG repos for Victoria and Ussuri will be updated and tested for both CentOS Stream and CentOS Linux 8 until end of 2021 and then continue on CentOS Stream.
• We will create and test new RDO CloudSIG repos for Victoria and Ussuri on CentOS Stream 8.
• The RDO Trunk repositories (aka DLRN repos) will be built and tested using CentOS 8 Stream buildroot for all releases currently using CentOS Linux 8 (since Train on)

How do we plan to implement these changes?

• We will keep building packages just once. We will move buildroots for both DLRN and CloudSIG to use CentOS Stream 8 in the near future.
• For Ussuri and Victoria CloudSIG repos, while we are supporting both C8 and C8S, we will be utilizing separated CBS Tags. This will allow us to have separated repositories, promotion jobs and package versions for each OS.
• In order to reduce the impact of potential issues and discover issues related to C8S as soon as possible, we will put more focus on periodic jobs on C8S.
• At a later stage, we will move the CI jobs used to gate changes in distgits to use C8S instead of C8 for all RDO releases where we use CentOS 8.
• The CentOS/RHEL team has made public their interest in applying Continuous Delivery approach to CentOS Stream to provide a stable CentOS Stream using gating integration jobs. Our intent is to collaborate with the CentOS team on any initiatives that will help to validate RDO as early in the delivery pipeline as possible and reduce the impact on potential issues.

What’s next?

Recently, I bought a couple of Raspberry Pi 4, one with 4 GB and 2 equipped with 8 GB of RAM. When I bought the first one, there was no option to get bigger memory. However, I saw this as a game and thought to give this a try. I also bought SSDs for these and USB3 to SATA adapters. Before purchasing anything, you may want to take a look at James Archers page. Unfortunately, there are a couple on adapters on the marked, which don't work that well.

Deploying Fedora 33 Server

Initially, I followed the description to deploy Fedora 32; it works the same way for Fedora 33 Server (in my case here).

Because ceph requires a partition (or better: a whole disk), I used the traditional setup using partitions and no LVM.

Deploying Kubernetes

git clone https://github.com/kubernetes-sigs/kubespray
cd kubespray

I followed the documentation and created an inventory. For the container runtime, I picked crio, and as calico as network plugin.

Because of an issue, I had to patch roles/download/defaults/main.yml:

diff --git a/roles/download/defaults/main.yml b/roles/download/defaults/main.yml
index a97be5a6..d4abb341 100644
--- a/roles/download/defaults/main.yml
+++ b/roles/download/defaults/main.yml
@@ -64,7 +64,7 @@ quay_image_repo: "quay.io"

 # TODO(mattymo): Move calico versions to roles/network_plugins/calico/defaults
 # after migration to container download
-calico_version: "v3.16.5"
+calico_version: "v3.15.2"
 calico_ctl_version: "{{ calico_version }}"
 calico_cni_version: "{{ calico_version }}"
 calico_policy_version: "{{ calico_version }}"
@@ -520,13 +520,13 @@ etcd_image_tag: "{{ etcd_version }}{%- if image_arch != 'amd64' -%}-{{ image_arc
 flannel_image_repo: "{{ quay_image_repo }}/coreos/flannel"
 flannel_image_tag: "{{ flannel_version }}"
 calico_node_image_repo: "{{ quay_image_repo }}/calico/node"
-calico_node_image_tag: "{{ calico_version }}"
+calico_node_image_tag: "{{ calico_version }}-arm64"
 calico_cni_image_repo: "{{ quay_image_repo }}/calico/cni"
-calico_cni_image_tag: "{{ calico_cni_version }}"
+calico_cni_image_tag: "{{ calico_cni_version }}-arm64"
 calico_policy_image_repo: "{{ quay_image_repo }}/calico/kube-controllers"
-calico_policy_image_tag: "{{ calico_policy_version }}"
+calico_policy_image_tag: "{{ calico_policy_version }}-arm64"
 calico_typha_image_repo: "{{ quay_image_repo }}/calico/typha"
-calico_typha_image_tag: "{{ calico_typha_version }}"
+calico_typha_image_tag: "{{ calico_typha_version }}-arm64"
 pod_infra_image_repo: "{{ kube_image_repo }}/pause"
 pod_infra_image_tag: "{{ pod_infra_version }}"
 install_socat_image_repo: "{{ docker_image_repo }}/xueshanf/install-socat"

Deploy Ceph

Ceph requires a raw partition. Make sure, you have an empty partition available.

[root@node1 ~]# lsblk -f
NAME FSTYPE FSVER LABEL UUID                                   FSAVAIL FSUSE% MOUNTPOINT
sda
├─sda1
│    vfat   FAT32 UEFI  7DC7-A592
├─sda2
│    vfat   FAT32       CB75-24A9                               567.9M     1% /boot/efi
├─sda3
│    xfs                cab851cb-1910-453b-ae98-f6a2abc7f0e0    804.7M    23% /boot
├─sda4
│
├─sda5
│    xfs                6618a668-f165-48cc-9441-98f4e2cc0340     27.6G    45% /
└─sda6

In my case, there are sda4 and sda6 not formatted. sda4 is very small and will be ignored, sda6 will be used.

Using rook is pretty straightforward

git clone --single-branch --branch v1.5.4 https://github.com/rook/rook.git
cd rook/cluster/examples/kubernetes/ceph
kubectl create -f crds.yaml -f common.yaml -f operator.yaml
kubectl create -f cluster.yaml

While reviewing  the comments on the Ironic spec, for Secure RBAC. I had to ask myself if the “project” construct makes sense for Ironic.  I still think it does, but I’ll write this down to see if I can clarify it for me, and maybe for you, too.

Baremetal servers change.  The whole point of Ironic is to control the change of Baremetal servers from inanimate pieces of metal to “really useful engines.”  This needs to happen in a controlled and unsurprising way.

Ironic the server does what it is told. If a new piece of metal starts sending out DHCP requests, Ironic is going to PXE boot it.  This is the start of this new piece of metals journey of self discovery.  At least as far as Ironic is concerned.

But really, someone had to rack and wire said piece of metal.  Likely the person that did this is not the person that is going to run workloads on it in the end.  They might not even work for the same company;  they might be a delivery person from Dell or Supermicro.  So, once they are done with it, they don’t own it any more.

Who does?  Who owns a piece of metal before it is enrolled in the OpenStack baremetal service?

No one.  It does not exist.

Ok, so lets go back to someone pushing the button, booting our server for the first time, and it doing its PXE boot thing.

Or, we get the MAC address and enter that into the ironic database, so that when it does boot, we know about it.

Either way, Ironic is really the playground monitor, just making sure it plays nice.

What if Ironic is a multi-tenant system?  Someone needs to be able to transfer the baremetal server from where ever it lands up front to the people that need to use it.

I suspect that ransferring metal from project to project is going to be one of the main use cases after the sun has set on day one.

So, who should be allowed to say what project a piece of baremetal can go to?

Well, in Keystone, we have the idea of hierarchy.  A Project is owned by a domain, and a project can be nested inside another project.

But this information is not passed down to Ironic.  There is no way to get a token for a project that shows its parent information.  But a remote service could query the project hierarchy from Keystone. 

https://docs.openstack.org/api-ref/identity/v3/?expanded=show-project-details-detail#show-project-details

Say I want to transfer a piece of metal from one project to another.  Should I have a token for the source project or the remote project.  Ok, dump question, I should definitely have a token for the source project.  The smart question is whether I should also have a token for the destination project.

Sure, why not.  Two tokens. One has the “delete” role and one that has the “create” role.

The only problem is that nothing like this exists in Open Stack.  But it should.

We could fake it with hierarchy;  I can pass things up and down the project tree.  But that really does not one bit of good.  People don’t really use the tree like that.  They should.  We built a perfectly nice tree and they ignore it.  Poor, ignored, sad, lonely tree.

Actually, it has no feelings.  Please stop anthropomorphising the tree.

What you could do is create the destination object, kind of a potential piece-of-metal or metal-receiver.  This receiver object gets  a UUID.  You pass this UUID to the “move” API. But you call the MOVE api with a token for the source project.   The move is done atomically. Lets call this thing identified by a UUID a move-request. 

The order of operations could be done in reverse.  The operator could create the move request on the source, and then pass that to the receiver.  This might actually make mores sense, as you need to know about the object before you can even think to move it.

Both workflows seem to have merit.

And…this concept seems to be something that OpenStack needs in general. 

Infact, why should the API not be a generic API. I mean, it would have to be per service, but the same API could be used to transfer VMs between projects in Nova nad between Volumes in Cinder. The API would have two verbs one for creating a new move request, and one for accepting it.

POST /thingy/v3.14/resource?resource_id=abcd&destination=project_id

If this is called with a token, it needs to be scoped. If it is scoped to the project_id in the API, it creates a receiving type request. If it is scoped to the project_id that owns the resource, it is a sending type request. Either way, it returns an URL. Call GET on that URL and you get information about the transfer. Call PATCH on it with the appropriately scoped token, and the resource is transferred. And maybe enough information to prove that you know what you are doing: maybe you have to specify the source and target projects in that patch request.

A foolish consistency is the hobgoblin of little minds.

Edit: OK, this is not a new idea. Cinder went through the same thought process according to Duncan Thomas. The result is this API: https://docs.openstack.org/api-ref/block-storage/v3/index.html#volume-transfer

Which looks like it then morphed to this one:

https://docs.openstack.org/api-ref/block-storage/v3/index.html#volume-transfers-volume-transfers-3-55-or-later

I've had to re-teach myself how to do this so I'm writing my own notes.

Prerequisites:

1. Get a working undercloud (perhaps from tripleo-lab)
2. git clone https://git.openstack.org/openstack/tripleo-ansible.git ; cd tripleo-ansible
3. Determine the test name: ls roles

Once you have your environment ready run a test with the name from step 3.

./scripts/run-local-test tripleo_derived_parameters

 export TRIPLEO_JOB_ANSIBLE_ARGS="--skip-tags run_ceph_ansible,run_uuid_ansible,ceph_client_rsync,clean_fetch_dir"
 ./scripts/run-local-test tripleo_ceph_run_ansible

This last tip should get added to the docs.

Look back at our Pushing Keystone over the Edge presentation from the OpenStack Summit. Many of the points we make are problems faced by any application trying to scale across multiple datacenters. Cassandra is a database designed to deal with this level of scale. So Cassandra may well be a better choice than MySQL or other RDBMS as a datastore to Keystone. What would it take to enable Cassandra support for Keystone?

Lets start with the easy part: defining the tables. Lets look at how we define the Federation back end for SQL. We use SQL Alchemy to handle the migrations: we will need something comparable for Cassandra Query Language (CQL) but we also need to translate the table definitions themselves.

Before we create the tables, we need to create keyspace. I am going to make separate keyspaces for each of the subsystems in Keystone: Identity, Assignment, Federation, and so on. Here’s the Federated one:

CREATE KEYSPACE keystone_federation WITH replication = {'class': 'NetworkTopologyStrategy', 'datacenter1': '3'}  AND durable_writes = true;

The Identity provider table is defined like this:

    idp_table = sql.Table(
        'identity_provider',
        meta,
        sql.Column('id', sql.String(64), primary_key=True),
        sql.Column('enabled', sql.Boolean, nullable=False),
        sql.Column('description', sql.Text(), nullable=True),
        mysql_engine='InnoDB',
        mysql_charset='utf8')
    idp_table.create(migrate_engine, checkfirst=True)

The comparable CQL to create a table would look like this:

CREATE TABLE identity_provider (id text PRIMARY KEY , enables boolean , description text);

However, when I describe the schema to view the table defintion, we see that there are many tuning and configuration parameters that are defaulted:

CREATE TABLE federation.identity_provider (
    id text PRIMARY KEY,
    description text,
    enables boolean
) WITH additional_write_policy = '99p'
    AND bloom_filter_fp_chance = 0.01
    AND caching = {'keys': 'ALL', 'rows_per_partition': 'NONE'}
    AND cdc = false
    AND comment = ''
    AND compaction = {'class': 'org.apache.cassandra.db.compaction.SizeTieredCompactionStrategy', 'max_threshold': '32', 'min_threshold': '4'}
    AND compression = {'chunk_length_in_kb': '16', 'class': 'org.apache.cassandra.io.compress.LZ4Compressor'}
    AND crc_check_chance = 1.0
    AND default_time_to_live = 0
    AND extensions = {}
    AND gc_grace_seconds = 864000
    AND max_index_interval = 2048
    AND memtable_flush_period_in_ms = 0
    AND min_index_interval = 128
    AND read_repair = 'BLOCKING'
    AND speculative_retry = '99p';

I don’t know Cassandra well enough to say if these are sane defaults to have in production. I do know that someone, somewhere, is going to want to tweak them, and we are going to have to provide a means to do so without battling the upgrade scripts. I suspect we are going to want to only use the short form (what I typed into the CQL prompt) in the migrations, not the form with all of the options. In addition, we might want an if not exists  clause on the table creation to allow people to make these changes themselves. Then again, that might make things get out of sync. Hmmm.

There are three more entities in this back end:

CREATE TABLE federation_protocol (id text, idp_id text, mapping_id text,  PRIMARY KEY(id, idp_id) );
cqlsh:federation> CREATE TABLE mapping (id text primary key, rules text,    );
CREATE TABLE service_provider ( auth_url text, id text primary key, enabled boolean, description text, sp_url text, RELAY_STATE_PREFIX  text);

One thing that is interesting is that we will not be limiting the ID fields to 32, 64, or 128 characters. There is no performance benefit to doing so in Cassandra, nor is there any way to enforce the length limits. From a Keystone perspective, there is not much value either; we still need to validate the UUIDs in Python code. We could autogenerate the UUIDs in Cassandra, and there might be some benefit to that, but it would diverge from the logic in the Keystone code, and explode the test matrix.

There is only one foreign key in the SQL section; the federation protocol has an idp_id that points to the identity provider table. We’ll have to accept this limitation and ensure the integrity is maintained in code. We can do this by looking up the Identity provider before inserting the protocol entry. Since creating a Federated entity is a rare and administrative task, the risk here is vanishingly small. It will be more significant elsewhere.

For access to the database, we should probably use Flask-CQLAlchemy. Fortunately, Keystone is already a Flask based project, so this makes the two projects align.

For migration support, It looks like the best option out there is cassandra-migrate.

An effort like this would best be started out of tree, with an expectation that it would be merged in once it had shown a degree of maturity. Thus, I would put it into a namespace that would not conflict with the existing keystone project. The python imports would look like:

from keystone.cassandra import migrations
from keystone.cassandra import identity
from keystone.cassandra import federation

This could go in its own git repo and be separately pip installed for development. The entrypoints would be registered such that the configuration file would have entries like:

Any tuning of the database could be put under a [cassandra] section of the conf file, or tuning for individual sections could be in keys prefixed with cassanda_ in the appropriate sections, such as application_credentials as shown above.

It might be interesting to implement a Cassandra token backend and use the default_time_to_live value on the table to control the lifespan and automate the cleanup of the tables. This might provide some performance benefit over the fernet approach, as the token data would be cached. However, the drawbacks due to token invalidation upon change of data would far outweigh the benefits unless the TTL was very short, perhaps 5 minutes.

Just making it work is one thing. In a follow on article, I’d like to go through what it would take to stretch a cluster from one datacenter to another, and to make sure that the other considerations that we discussed in that presentation are covered.

Feedback?

RDO Victoria Released

The RDO community is pleased to announce the general availability of the RDO build for OpenStack Victoria for RPM-based distributions, CentOS Linux and Red Hat Enterprise Linux. RDO is suitable for building private, public, and hybrid clouds. Victoria is the 22nd release from the OpenStack project, which is the work of more than 1,000 contributors from around the world.

The release is already available on the CentOS mirror network at http://mirror.centos.org/centos/8/cloud/x86_64/openstack-victoria/.

The RDO community project curates, packages, builds, tests and maintains a complete OpenStack component set for RHEL and CentOS Linux and is a member of the CentOS Cloud Infrastructure SIG. The Cloud Infrastructure SIG focuses on delivering a great user experience for CentOS Linux users looking to build and maintain their own on-premise, public or hybrid clouds.

All work on RDO and on the downstream release, Red Hat OpenStack Platform, is 100% open source, with all code changes going upstream first.

PLEASE NOTE: RDO Victoria provides packages for CentOS8 and python 3 only. Please use the Train release, for CentOS7 and python 2.7.

Interesting things in the Victoria release include:

• With the Victoria release, source tarballs are validated using the upstream GPG signature. This certifies that the source is identical to what is released upstream and ensures the integrity of the packaged source code.
• With the Victoria release, openvswitch/ovn are not shipped as part of RDO. Instead RDO relies on builds from the CentOS NFV SIG.
• Some new packages have been added to RDO during the Victoria release:
  • ansible-collections-openstack: This package includes OpenStack modules and plugins which are supported by the OpenStack community to help with the management of OpenStack infrastructure.
  • ansible-tripleo-ipa-server: This package contains Ansible for configuring the FreeIPA server for TripleO.
  • python-ibmcclient: This package contains the python library to communicate with HUAWEI iBMC based systems.
  • puppet-powerflex: This package contains the puppet module needed to deploy PowerFlex with TripleO.
  • The following packages have been retired from the RDO OpenStack distribution in the Victoria release:
    • The Congress project, an open policy framework for the cloud, has been retired upstream and from the RDO project in the Victoria release.
    • neutron-fwaas, the Firewall as a Service driver for neutron, is no longer maintained and has been removed from RDO.

Other highlights of the broader upstream OpenStack project may be read via https://releases.openstack.org/victoria/highlights.

Contributors
During the Victoria cycle, we saw the following new RDO contributors:

Amy Marrich (spotz)
Daniel Pawlik
Douglas Mendizábal
Lance Bragstad
Martin Chacon Piza
Paul Leimer
Pooja Jadhav
Qianbiao NG
Rajini Karthik
Sandeep Yadav
Sergii Golovatiuk
Steve Baker

Welcome to all of you and Thank You So Much for participating!

But we wouldn’t want to overlook anyone. A super massive Thank You to all 58 contributors who participated in producing this release. This list includes commits to rdo-packages, rdo-infra, and redhat-website repositories:

Adam Kimball
Ade Lee
Alan Pevec
Alex Schultz
Alfredo Moralejo
Amol Kahat
Amy Marrich (spotz)
Arx Cruz
Bhagyashri Shewale
Bogdan Dobrelya
Cédric Jeanneret
Chandan Kumar
Damien Ciabrini
Daniel Pawlik
Dmitry Tantsur
Douglas Mendizábal
Emilien Macchi
Eric Harney
Francesco Pantano
Gabriele Cerami
Gael Chamoulaud
Gorka Eguileor
Grzegorz Grasza
Harald Jensås
Iury Gregory Melo Ferreira
Jakub Libosvar
Javier Pena
Joel Capitao
Jon Schlueter
Lance Bragstad
Lon Hohberger
Luigi Toscano
Marios Andreou
Martin Chacon Piza
Mathieu Bultel
Matthias Runge
Michele Baldessari
Mike Turek
Nicolas Hicher
Paul Leimer
Pooja Jadhav
Qianbiao.NG
Rabi Mishra
Rafael Folco
Rain Leander
Rajini Karthik
Riccardo Pittau
Ronelle Landy
Sagi Shnaidman
Sandeep Yadav
Sergii Golovatiuk
Slawek Kaplonski
Soniya Vyas
Sorin Sbarnea
Steve Baker
Tobias Urdin
Wes Hayutin
Yatin Karel

The Next Release Cycle
At the end of one release, focus shifts immediately to the next release i.e Wallaby.

Get Started
There are three ways to get started with RDO.

To spin up a proof of concept cloud, quickly, and on limited hardware, try an All-In-One Packstack installation. You can run RDO on a single node to get a feel for how it works.

For a production deployment of RDO, use TripleO and you’ll be running a production cloud in short order.

Finally, for those that don’t have any hardware or physical resources, there’s the OpenStack Global Passport Program. This is a collaborative effort between OpenStack public cloud providers to let you experience the freedom, performance and interoperability of open source infrastructure. You can quickly and easily gain access to OpenStack infrastructure via trial programs from participating OpenStack public cloud providers around the world.

Get Help
The RDO Project has our users@lists.rdoproject.org for RDO-specific users and operators. For more developer-oriented content we recommend joining the dev@lists.rdoproject.org mailing list. Remember to post a brief introduction about yourself and your RDO story. The mailing lists archives are all available at https://mail.rdoproject.org. You can also find extensive documentation on RDOproject.org.

The #rdo channel on Freenode IRC is also an excellent place to find and give help.

We also welcome comments and requests on the CentOS devel mailing list and the CentOS and TripleO IRC channels (#centos, #centos-devel, and #tripleo on irc.freenode.net), however we have a more focused audience within the RDO venues.

Get Involved
To get involved in the OpenStack RPM packaging effort, check out the RDO contribute pages, peruse the CentOS Cloud SIG page, and inhale the RDO packaging documentation.

Join us in #rdo and #tripleo on the Freenode IRC network and follow us on Twitter @RDOCommunity. You can also find us on Facebook and YouTube.

TheJulia was kind enough to update the docs for Ironic to show me how to include IPMI information when creating nodes.

To all delete the old nodes

for UUID in `openstack baremetal node list -f json | jq -r '.[] | .UUID' ` ; do openstack baremetal node delete $UUID; done

nodes definition

I removed the ipmi common data from each definition as there is a password there, and I will set that afterwards on all nodes.

{
  "nodes": [
    {
      "ports": [
        {
          "address": "00:21:9b:93:d0:90"
        }
      ],
      "name": "zygarde",
      "driver": "ipmi",
      "driver_info": {
      		"ipmi_address":  "192.168.123.10"
      }
    },
    {
      "ports": [
        {
          "address": "00:21:9b:9b:c4:21"
        }
      ],
      "name": "umbreon",
      "driver": "ipmi",
      "driver_info": {
	      "ipmi_address": "192.168.123.11"
	}
      },	
    {
      "ports": [
        {
          "address": "00:21:9b:98:a3:1f"
        }
      ],
      "name": "zubat",
      "driver": "ipmi",
       "driver_info": {
	      "ipmi_address": "192.168.123.12"
       }
    }
  ]
}

Create the nodes

openstack baremetal create  ./nodes.ipmi.json 

Check that the nodes are present

$ openstack baremetal node list
+--------------------------------------+---------+---------------+-------------+--------------------+-------------+
| UUID                                 | Name    | Instance UUID | Power State | Provisioning State | Maintenance |
+--------------------------------------+---------+---------------+-------------+--------------------+-------------+
| 3fa4feae-0d5c-4e38-a012-29258d40651b | zygarde | None          | None        | enroll             | False       |
| 00965ad4-c972-46fa-948a-3ce87aecf5ac | umbreon | None          | None        | enroll             | False       |
| 8702ea0c-aa10-4542-9292-3b464fe72036 | zubat   | None          | None        | enroll             | False       |
+--------------------------------------+---------+---------------+-------------+--------------------+-------------+

Update IPMI common data

for UUID in `openstack baremetal node list -f json | jq -r '.[] | .UUID' ` ; 
do  openstack baremetal node set $UUID --driver-info ipmi_password=`cat ~/ipmi.password`  --driver-info   ipmi_username=admin   ; 
done

EDIT: I had ipmi_user before and it does not work. Needs to be ipmi_username.

Final Check

And if I look in the returned data for the definition, we see the password is not readable:

$ openstack baremetal node show zubat  -f yaml | grep ipmi_password
  ipmi_password: '******'

Power On

for UUID in `openstack baremetal node list -f json | jq -r '.[] | .UUID' ` ; do  openstack baremetal node power on $UUID  ; done

Change “on” to “off” to power off.

“I can do any thing. I can’t do everything.”

The sheer number of projects and problem domains covered by OpenStack was overwhelming. I never learned several of the other projects under the big tent. One project that is getting relevant to my day job is Ironic, the bare metal provisioning service. Here are my notes from spelunking the code.

The Setting

I want just Ironic. I don’t want Keystone (personal grudge) or Glance or Neutron or Nova.

Ironic will write files to e.g. /var/lib/tftp and /var/www/html/pxe and will not handle DHCP, but can make sue of static DHCP configurations.

Ironic is just an API server at this point ( python based web service) that manages the above files, and that can also talk to the IPMI ports on my servers to wake them up and perform configurations on them.

I need to provide ISO images to Ironic so it can put the in the right place to boot them

Developer steps

I checked the code out of git. I am working off the master branch.

I ran tox to ensure the unit tests are all at 100%

I have mysql already installed and running, but with a Keystone Database. I need to make a new one for ironic. The database name, user, and password are all going to be ironic, to keep things simple.

CREATE USER 'ironic'@'localhost' IDENTIFIED BY 'ironic';
create database ironic;
GRANT ALL PRIVILEGES ON ironic.* TO 'ironic'@'localhost';
FLUSH PRIVILEGES;

Note that I did this as the Keystone user. That dude has way to much privilege….good thing this is JUST for DEVELOPMENT. This will be used to follow the steps in the developers quickstart docs. I also set the mysql URL in the config file to this

connection = mysql+pymysql://ironic:ironic@localhost/ironic

Then I can run ironic db sync. Lets’ see what I got:

mysql ironic --user ironic --password
#....
MariaDB [ironic]> show tables;
+-------------------------------+
| Tables_in_ironic              |
+-------------------------------+
| alembic_version               |
| allocations                   |
| bios_settings                 |
| chassis                       |
| conductor_hardware_interfaces |
| conductors                    |
| deploy_template_steps         |
| deploy_templates              |
| node_tags                     |
| node_traits                   |
| nodes                         |
| portgroups                    |
| ports                         |
| volume_connectors             |
| volume_targets                |
+-------------------------------+
15 rows in set (0.000 sec)

OK, so the first table shows that Ironic uses Alembic to manage migrations. Unlike the SQLAlchemy migrations table, you can’t just query this table to see how many migrations have been performed:

MariaDB [ironic]> select * from alembic_version;
+--------------+
| version_num  |
+--------------+
| cf1a80fdb352 |
+--------------+
1 row in set (0.000 sec)

Running The Services

The script to start the API server is:
ironic-api -d --config-file etc/ironic/ironic.conf.local

Looking in the file requirements.txt, I see that they Web framework for Ironic is Pecan:

$ grep pecan requirements.txt 
pecan!=1.0.2,!=1.0.3,!=1.0.4,!=1.2,>=1.0.0 # BSD

This is new to me. On Keystone, we converted from no framework to Flask. I’m guessing that if I look in the chain that starts with ironic-api file, I will see a Pecan launcher for a web application. We can find that file with

$which ironic-api
/opt/stack/ironic/.tox/py3/bin/ironic-api

Looking in that file, it references ironic.cmd.api, which is the file ironic/cmd/api.py which in turn refers to ironic/common/wsgi_service.py. This in turn refers to ironic/api/app.py from which we can finally see that it imports pecan.

Now I am ready to run the two services. Like most of OpenStack, there is an API server and a “worker” server. In Ironic, this is called the Conductor. This maps fairly well to the Operator pattern in Kubernetes. In this pattern, the user makes changes to the API server via a web VERB on a URL, possibly with a body. These changes represent a desired state. The state change is then performed asynchronously. In OpenStack, the asynchronous communication is performed via a message queue, usually Rabbit MQ. The Ironic team has a simpler mechanism used for development; JSON RPC. This happens to be the same mechanism used in FreeIPA.

Command Line

OK, once I got the service running, I had to do a little fiddling around to get the command lines to work. The was an old reference to

OS_AUTH_TYPE=token_endpoint

which needed to be replaces with

OS_AUTH_TYPE=none

Both are in the documentation, but only the second one will work.

I can run the following commands:

$ baremetal driver list
+---------------------+----------------+
| Supported driver(s) | Active host(s) |
+---------------------+----------------+
| fake-hardware       | ayoungP40      |
+---------------------+----------------+
$ baremetal node list

curl

Lets see if I can figure out from CURL what APIs those are…There is only one version, and one link, so:

curl http://127.0.0.1:6385 | jq '.versions  | .[] | .links | .[] |  .href'

"http://127.0.0.1:6385/v1/"

Doing curl against that second link gives a list of the top level resources:

• media_types
• chassis
• nodes
• drivers

And I assume that, if I use curl to GET the drivers, I should see the fake driver entry from above:

$ curl "http://127.0.0.1:6385/v1/drivers" | jq '.drivers |.[] |.name'

"fake-hardware"

OK, that is enough to get started. I am going to try and do the same with the RPMs that we ship with OSP and see what I get there.

But that is a tale for another day.

Thank You

I had a conversation I had with Julia Kreger, a long time core member of the Ironic project. This helped get me oriented.

 curl https://bootstrap.pypa.io/get-pip.py -o get-pip.py
 python3 get-pip.py
 pip install tox

  cd /home/stack/tripleo-docs
  tox -e deploy-guide

 tox -e linters
 tox -e pep8

 cd /home/stack/tripleo-common
 tox -e py36 -- tripleo_common.tests.test_inventory.TestInventory.test_get_roles_by_service

 cd /home/stack/tripleo-ansible
 tox -e py36 -- tripleo_ansible.tests.modules.test_derive_hci_parameters.TestTripleoDeriveHciParameters

This is mostly a brain dump for myself for later reference, but may be also useful for others.

As I wrote in an earlier post, collectd is configured on OpenStack TripleO driven deployments by a config file.

parameter_defaults:
    CollectdExtraPlugins:
        - write_http
    ExtraConfig:
        collectd::plugin::write_http::nodes:
            collectd:
                url: collectd1.tld.org
                metrics: true
                header: foobar

The collectd exec plugin comes handy when launching some third party script. However, the config may be a bit tricky, for example to execute /usr/bin/true one would insert

parameter_defaults:
    CollectdExtraPlugins:
     - exec
    ExtraConfig:
      collectd::plugin::exec::commands:
        healthcheck:
          user: "collectd"
          group: "collectd"
          exec: ["/usr/bin/true",]

The RDO community is pleased to announce the general availability of the RDO build for OpenStack Ussuri for RPM-based distributions, CentOS Linux and Red Hat Enterprise Linux. RDO is suitable for building private, public, and hybrid clouds. Ussuri is the 21st release from the OpenStack project, which is the work of more than 1,000 contributors from around the world.

The release is already available on the CentOS mirror network at http://mirror.centos.org/centos/8/cloud/x86_64/openstack-ussuri/.

The RDO community project curates, packages, builds, tests and maintains a complete OpenStack component set for RHEL and CentOS Linux and is a member of the CentOS Cloud Infrastructure SIG. The Cloud Infrastructure SIG focuses on delivering a great user experience for CentOS Linux users looking to build and maintain their own on-premise, public or hybrid clouds.

All work on RDO and on the downstream release, Red Hat OpenStack Platform, is 100% open source, with all code changes going upstream first.

PLEASE NOTE: At this time, RDO Ussuri provides packages for CentOS8 only. Please use the previous release, Train, for CentOS7 and python 2.7.

Welcome to all of you and Thank You So Much for participating!

But we wouldn’t want to overlook anyone. A super massive Thank You to all 54 contributors who participated in producing this release. This list includes commits to rdo-packages and rdo-infra repositories:

Twice during each release cycle, RDO hosts official Test Days shortly after the first and third milestones; therefore, the upcoming test days are 25-26 June 2020 for Milestone One and 17-18 September 2020 for Milestone Three.

To spin up a proof of concept cloud, quickly, and on limited hardware, try an All-In-One Packstack installation. You can run RDO on a single node to get a feel for how it works.

For a production deployment of RDO, use the TripleO Quickstart and you’ll be running a production cloud in short order.

Finally, for those that don’t have any hardware or physical resources, there’s the OpenStack Global Passport Program. This is a collaborative effort between OpenStack public cloud providers to let you experience the freedom, performance and interoperability of open source infrastructure. You can quickly and easily gain access to OpenStack infrastructure via trial programs from participating OpenStack public cloud providers around the world.

The #rdo channel on Freenode IRC is also an excellent place to find and give help.

We also welcome comments and requests on the CentOS devel mailing list and the CentOS and TripleO IRC channels (#centos, #centos-devel, and #tripleo on irc.freenode.net), however we have a more focused audience within the RDO venues.

Join us in #rdo and #tripleo on the Freenode IRC network and follow us on Twitter @RDOCommunity. You can also find us on Facebook and YouTube.

Continue reading "Dutch Lock Down Day Forty Three"

Photo by Florian Krumm on Unsplash

Three incredible articles by Lars Kellogg-Stedman aka oddbit – mostly about adjustments and such made due to COVID-19. I hope you’re keeping safe at home, RDO Stackers! Wash your hands and enjoy these three fascinating articles about keyboards, arduino and machines that go ping…

Some thoughts on Mechanical Keyboards by oddbit

Since we’re all stuck in the house and working from home these days, I’ve had to make some changes to my home office. One change in particular was requested by my wife, who now shares our rather small home office space with me: after a week or so of calls with me clattering away on my old Das Keyboard 3 Professional in the background, she asked if I could get something that was maybe a little bit quieter.

Read more at https://blog.oddbit.com/post/2020-04-15-some-thoughts-on-mechanical-ke/

Grove Beginner Kit for Arduino (part 1) by oddbit

The folks at Seeed Studio have just released the Grove Beginner Kit for Arduino, and they asked if I would be willing to take a look at it in exchange for a free kit. At first glance it reminds me of the Radio Shack (remember when they were cool?) electronics kit I had when I was a kid – but somewhat more advanced. I’m excited to take a closer look, but given shipping these days means it’s probably a month away at least.

Read more at https://blog.oddbit.com/post/2020-04-15-grove-beginner-kit-for-arduino/

I see you have the machine that goes ping… by oddbit

We’re all looking for ways to keep ourselves occupied these days, and for me that means leaping at the chance to turn a small problem into a slightly ridiculous electronics project. For reasons that I won’t go into here I wanted to generate an alert when a certain WiFi BSSID becomes visible. A simple solution to this problem would have been a few lines of shell script to send me an email…but this article isn’t about simple solutions!

Read more at https://blog.oddbit.com/post/2020-03-20-i-see-you-have-the-machine-tha/

While a lot of RDO contributors are remote, there are many more who are not and now find themselves in lock down or working from home due to the coronavirus. A few members of the RDO community requested tips, tricks, and best practices for working on and managing a distributed team.

Connectivity

I mean, obviously, there needs to be enough bandwidth, which might normally be just fine, but if you have a partner and kids also using the internet, video calls might become impossible.

Communicate with the family to work out a schedule or join the call without video so you can still participate.

Manage Expectations

Even if you’re used to being remote AND don’t have a partner / family invading your space, there is added stress in the new reality.

Be sure to manage expectations with your boss about priorities, focus, goals, project tracking, and mental health.

This will be an ongoing conversation that evolves as projects and situations evolve.

Know Thyself

Some people NEED to get ready in the morning, dress in business clothes, and work in a specific space. Some people can wake up, grab their laptop and work from the bed.

Some people NEED to get up once an hour to walk around the block. Some people are content to take a break once every other hour or more.

Some people NEED to physically be in the office around other people. Some will be totally content to work from home.

Sure, some things aren’t optional, but work with what you can.

Figure out what works for you.

Embrace #PhysicalDistance Not #SocialDistance

Remember to stay connected socially with your colleagues. Schedule a meeting without an agenda where you chat about whatever.

Come find the RDO Technical Community Liaison, leanderthal, and your other favorite collaborators on Freenode IRC on channels #rdo and #tripleo.

For that matter, don’t forget to reach out to your friends and family.

Even introverts need to maintain a certain level of connection.

Further Reading

There’s a ton of information about working remotely / distributed productivity and this is, by no means, an exhaustive list, but to get you started:

• Ergonomic Essentials for Remote Working
• Cornell University Ergonomics
• Wikipedia.Org Time Management
• You’re Taking Breaks The Wrong Way
• WHO | Health Workforce Burnout
• Wikipedia.Org Stress Management
• Lessons from Community Leaders on Working Remote
• Top 15 Tips To Effectively Manage Remote Employees

Now let’s hear from you!

What tips, tricks, and resources do you recommend to work from home, especially in this time of stress? Please add your advice in the comments below.

And, as always, thank you for being a part of the RDO community!

Oddbit writes two incredible articles – one about configuring passwordless consoles for raspberry pi and another about configuring open vswitch with nmcli while Carlos Camacho publishes Emilien Macchi’s deep dive demo on containerized deployment sans Paunch.

A passwordless serial console for your Raspberry Pi by oddbit

legendre on #raspbian asked:

How can i config rasp lite to open a shell on the serial uart on boot? Params are 1200-8-N-1 Dont want login running, just straight to sh

In this article, we’ll walk through one way of implementing this configuration.

Read more at https://blog.oddbit.com/post/2020-02-24-a-passwordless-serial-console/

TripleO deep dive session #14 (Containerized deployments without paunch) by Carlos Camacho

This is the 14th release of the TripleO “Deep Dive” sessions. Thanks to Emilien Macchi for this deep dive session about the status of the containerized deployment without Paunch.

Read more at https://www.anstack.com/blog/2020/02/18/tripleo-deep-dive-session-14.html

Configuring Open vSwitch with nmcli by oddbit

I recently acquired a managed switch for my home office in order to segment a few devices off onto their own isolated vlan. As part of this, I want to expose these vlans on my desktop using Open vSwitch (OVS), and I wanted to implement the configuration using NetworkManager rather than either relying on the legacy /etc/sysconfig/network-scripts scripts or rolling my own set of services. These are my notes in case I ever have to do this again.

Read more at https://blog.oddbit.com/post/2020-02-15-configuring-open-vswitch-with/

This is the 14th release of the TripleO “Deep Dive” sessions

Thanks to Emilien Macchi for this deep dive session about the status of the containerized deployment without Paunch.

You can access the presentation.

So please, check the full session content on the TripleO YouTube channel.

Please check the sessions index to have access to all available content.

Yes, upgrades are hard

• Providing RDO Train packages on CentOS8. This allows users to choose between doing a one-step upgrade from CentOS7/Train -> CentOS8/Ussuri or split it in two steps CentOS7/Train -> CentOS8/Train -> CentOS8/Ussuri.
• RDO maintains OpenStack packages during the whole upstream maintenance cycle – for the Train release, this is until April 2021. Operators can take some time to plan and execute their migration paths.

What “Supporting a OpenStack release in a CentOS version” means in RDO

Build

• Before we can start building OpenStack packages we need to have all required dependencies used to build or run OpenStack services. We use the libraries from CentOS base repos as much as we can and avoid rebasing or forking CentOS base packages unless it’s strongly justified.
• OpenStack packages are built using DLRN in RDO Trunk repos or CBS using jobs running in post pipeline in review.rdoproject.org.
• RDO also consumes packages from other CentOS SIGs as Ceph from Storage SIG, KVM from Virtualization or collectd from OpsTools.

Validate

• We run CI jobs periodically to validate the packages provided in the repos. These jobs are executed using the Zuul instance in SoftwareFactory project or Jenkins in CentOS CI infra and deploy different configurations of OpenStack using Packstack, puppet-openstack-integration and TripleO.
• Also, some upstream projects include CI jobs on CentOS using the RDO packages to gate every change on it.

Publish

• RDO Trunk packages are published in https://trunk.rdoproject.org and validated repositories are moved to promoted links.
• RDO CloudSIG packages are published in official CentOS mirrors after they are validated by CI jobs.

Challenges to provide python 3 packages for RDO Ussuri in CentOS 7

Build

• While CentOS 7 includes a quite wide set of python 2 modules (150+) in addition to the interpreter, the python 3 stack included in CentOS 7.7 is just the python interpreter and ~5 python modules. All the missing ones would need to be bootstraped for python3.
• Some python bindings are provided as part of other builds, i.e. python-rbd or python-rados is part of Ceph in StorageSIG, python-libguestfs is part of libguestfs in base repo, etc… RDO doesn’t own those packages so commitment from the owners would be needed or RDO would need to take ownership of them in this specific release (which means maintaining them until Train EOL).
• Current specs in Ussuri tie python version to CentOS version. We’d need to figure out a way to switch python version in CentOS 7 via tooling configuration and macros.

Validate

• In order to validate the python3 builds for Ussuri on CentOS 7, the deployment tools (puppet-openstack, packstack, kolla and TripleO) would need upstream fixes to install python3 packages instead of python2 for CentOS 7. Ideally, new CI jobs should be added with this configuration to gate changes in those repositores. This would require support from the upstream communities.

Conclusion

• Alternatives exist to help operators in the migration path from Train on CentOS 7 to Ussuri on CentOS 8 and avoid a massive full cloud reboot.
• Doing a full supported RDO release of Ussuri on CentOS 7 would require a big effort in RDO and other projects that can’t be done with existing resources:
  • It would required a full bootstrap of python3 dependencies which are pulled from CentOS base repositoris in python 2.
  • Other SIGs would need to provide python3 packages or, alternatively, RDO would need to maintain them for this specific release.
  • In order to validate the release upstream deployment projects would need to support this new python3 Train release.
• There may be chances for intermediate solutions limited to a reduced set of packages that would help in the transition period. We’d need to hear details from the interested community members about what would be actually needed and what’s the desired migration workflow. We will be happy to onboard new community members with interest in contributing to this effort.

We’re super chuffed to see another THREE posts from our illustrious community – Adam Young talks about api port failure and speed bumps while Lars explores literate programming.

Shift on Stack: api_port failure by Adam Young

I finally got a right-sized flavor for an OpenShift deployment: 25 GB Disk, 4 VCPU, 16 GB Ram. With that, I tore down the old cluster and tried to redeploy. Right now, the deploy is failing at the stage of the controller nodes querying the API port. What is going on?

Read more at https://adam.younglogic.com/2020/01/shift-on-stack-api_port-failure/

Self Service Speedbumps by Adam Young

The OpenShift installer is fairly specific in what it requires, and will not install into a virtual machine that does not have sufficient resources. These limits are 16 GB RAM, 4 Virtual CPUs, and 25 GB Disk Space. This is fairly frustrating if your cloud provider does not give you a flavor that matches this. The last item specifically is an artificial limitation as you can always create an additional disk and mount it, but the installer does not know to do that.

Read more at https://adam.younglogic.com/2020/01/self-service-speedbumps/

Snarl: A tool for literate blogging by Lars Kellogg-Stedman

Literate programming is a programming paradigm introduced by Donald Knuth in which a program is combined with its documentation to form a single document. Tools are then used to extract the documentation for viewing or typesetting or to extract the program code so it can be compiled and/or run. While I have never been very enthusiastic about literate programming as a development methodology, I was recently inspired to explore these ideas as they relate to the sort of technical writing I do for this blog.

Read more at https://blog.oddbit.com/post/2020-01-15-snarl-a-tool-for-literate-blog/

I finally got a right-sized flavor for an OpenShift deployment: 25 GB Disk, 4 VCPU, 16 GB Ram. With that, I tore down the old cluster and tried to redeploy. Right now, the deploy is failing at the stage of the controller nodes querying the API port. What is going on?

Here is the reported error on the console:

The IP address of 10.0.0.5 is attached to the following port:

$ openstack port list | grep "0.0.5"
| da4e74b5-7ab0-4961-a09f-8d3492c441d4 | demo-2tlt4-api-port       | fa:16:3e:b6:ed:f8 | ip_address='10.0.0.5', subnet_id='50a5dc8e-bc79-421b-aa53-31ddcb5cf694'      | DOWN   |

That final “DOWN” is the port state. It is also showing as detached. It is on the internal network:

Looking at the installer code, the one place I can find a reference to the api_port is in the template data/data/openstack/topology/private-network.tf used to build the value openstack_networking_port_v2. This value is used quite heavily in the rest of the installers’ Go code.

Looking in the terraform data built by the installer, I can find references to both the api_port and openstack_networking_port_v2. Specifically, there are several object of type openstack_networking_port_v2 with the names:

$ cat moc/terraform.tfstate  | jq -jr '.resources[] | select( .type == "openstack_networking_port_v2") | .name, ", ", .module, "\n" '
api_port, module.topology
bootstrap_port, module.bootstrap
ingress_port, module.topology
masters, module.topology

On a baremetal install, we need an explicit A record for api-int.<cluster_name>.<base_domain>. That requirement does not exist for OpenStack, however, and I did not have one the last time I installed.

api-int is the internal access to the API server. Since the controllers are hanging trying to talk to it, I assume that we are still at the stage where we are building the control plane, and that it should be pointing at the bootstrap server. However, since the port above is detached, traffic cannot get there. There are a few hypotheses in my head right now:

1. The port should be attached to the bootstrap device
2. The port should be attached to a load balancer
3. The port should be attached to something that is acting like a load balancer.

I’m leaning toward 3 right now.

The install-config.yaml has the line:
octaviaSupport: “1”

But I don’t think any Octavia resources are being used.

$ openstack loadbalancer pool list

$ openstack loadbalancer list

$ openstack loadbalancer flavor list
Not Found (HTTP 404) (Request-ID: req-fcf2709a-c792-42f7-b711-826e8bfa1b11)