2020-01-15 10:52:19 +00:00
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title: How to build an OpenStack alternative: Step 5, adding metadata
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pub_date: 2020-01-15
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author: ungleich virtualisation team
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twitter_handle: ungleich
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---
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_hidden: no
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---
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_discoverable: yes
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---
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abstract:
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Let the VMs get information about themselves
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---
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body:
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This time we describe how virtual machines can get information about
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themselves like which ssh keys should have access to it.
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The previous time we
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2020-01-15 12:30:36 +00:00
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[added a database to
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2020-01-15 10:52:19 +00:00
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uncloud](../how-to-build-an-openstack-alternative-step-4-adding-a-database/).
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## Motivation
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If we were to start VMs without a metadata service, all of the VMs
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would be looking identical and would not be able to know, whom to
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allow access to it.
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To customise a VM or to make it usable, we need to tell it who has
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access to it and potentially inject even more information.
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## Metadata service: how others do it
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Enters the metadata service. OpenNebula solves this problem quite
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nicely by attaching a virtual cdrom to the VMs. That cdrom contains
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only one file, `context.sh`. This file contains information about
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* networking
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* ssh keys
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OpenStack with cloud-init on the other side uses an HTTP based
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service that is found on the address `http://169.254.169.254/`.
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Both schemes come with disadvantages that we don't want to replicate
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in uncloud:
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In the opennebula case changing metadata information while the VM is
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running requires to create a new CDROM and if that one is still
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mounted, the VM might not get the up-to-date information. This is a
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bit of a theorethical case, as the metadata is rarely re-used after
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booting.
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However changing the information provided in the context.sh inside the
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ISO always requires to generate a new ISO. While technical possible,
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not very elegant.
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The OpenStack based approach has (from our point of view) a much
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bigger problem: it relies on IPv4. VMs running on uncloud primarily
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run IPv6 and should function without any IPv4 stack.
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The motivation for using the 169.254.0.0/16 network is clear: it works
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without having an IP address management system in place.
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## Solving it the smart way
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So it seems like the general approach of OpenStack/cloud-init is
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actually quite elegant, if it wasn't forcing IPv4.
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In the IPv6 world, we always have link local addresses in the
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**fe80::/10** network. Should we just replace the OpenStack approach
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with IPv6?
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We don't think so, it has the same argument in favor for IPv4 networks
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that we have in favor for IPv6 networks.
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Instead, we suggest to add a simple change to the OpenStack approach:
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Use http://metadata instead of using an IP address.
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## http://metadata
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So how should this work and why is this better than using
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http://169.254.169.254/?
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Using a name, it doesn't matter whether the VM is on an IPv4 ore
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IPv6 network.
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Using just the hostname, not an FQDN (i.e. metadata.example.com) makes
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it portable.
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The name can be resolved via various methods:
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* uncloud: it will be delivered by DNS
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* openstack: either via DNS (like uncloud) or if there is no IPAM, it
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can be statically set in /etc/hosts
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In the DNS resolving case, this actually gets even more interesting,
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because we can use the **DNS search path**. So while the client tries
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to resolve the hostname **metadata**, the underlying resolver library
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will also look for **metadata.example.com**, if example.com is in the
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search path.
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## uncloud implementation
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In uncloud we have implemented a sample [metadata
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service](https://code.ungleich.ch/uncloud/uncloud/tree/master/uncloud/metadata).
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However IPAM (i.e. router advertisements) and DNS servers are not part
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of uncloud and can be used from the regular system infrastructure.
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In one of the next versions we plan to include helpers that allow you
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to bootstrap IPAM and DNS easily.
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## Status
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At this point uncloud can create VMs and the VMs can get the ssh keys
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that should have access from the metadata service.
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With this latest add-on uncloud gets near the range of a usable
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prototype. A lot of things will probably need to be refactored in the
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future, but at the moment uncloud supports already:
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* creating VMs (using qemu)
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* securing the VM network (using nftables)
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* generating unique mac addresses (uncloud python code)
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* storing information in a distributed database (using pytho-etcd3 and
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etcd)
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* providing basic metadata inforamtion (uncloud python code)
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