Tag: cloudstack

ISC Kea DHCPv6 server

DHCPv6

In most situations StateLess Address AutoConfiguration (SLAAC) works just fine when you work with simple clients in a IPv6 network. But in other cases you want to assign pre-defined addresses or prefixes to clients and there DHCPv6 comes in to play.

While working on the IPv6 implementation for Apache CloudStack I found Kea, a DHCPv6 server from ISC.

DHCPv6 DUID

With IPv4 you could easily identify a client based on the MAC-address it send the DHCP request from. With IPv6 there is a DUID. The “DHCP Unique Identifier”. This is generated by the client and then used by the DHCPv6 server. A few possibilities the clients can choose from:

  • DUID-LL: DUID Based on Link-layer Address
  • DUID-LLT: Link-layer Address Plus Time
  • DUID-EN: Assigned by Vendor Based on Enterprise Number

While DUID seems nice, it can’t be dictated by the DHCPv6 server. The client generates the DUID itself and sends it towards the server. Not something you prefer if your are not in control of the clients.

In a cloud you are in control over the MAC-address, so that is what you want to use where possible. It can’t be spoofed by the client.

ISC Kea

Kea is a DHCPv4/DHCPv6 server being developed by the Internet Systems Consortium. It is a extensible and flexible DHCP server. Facebook uses it in their datacenters.

My goal was very simple. Set up Kea and see if I can use it to hand out an address to a client.

Configuration

I download the tarball and tested it with this configuration between two simple KVM VMs on my desktop.

{
    "Dhcp6": {
        "renew-timer": 1000,
        "rebind-timer": 2000,
        "preferred-lifetime": 3000,
        "valid-lifetime": 4000,
        "lease-database": {
            "type": "memfile",
            "persist": true,
            "name": "/tmp/kea-leases6.csv",
            "lfc-interval": 1800
        },
        "interfaces-config": {
            "interfaces": [ "eth1/2001:db8::1" ]
        },
        "mac-sources": ["duid"],
        "subnet6": [
            {
                "subnet": "2001:db8::/64",
                "id": 1024,
                "interface": "eth1",
                "pools": [
                    { "pool": "2001:db8::100-2001:db8::ffff" }
                ],
                "pd-pools": [
                    {
                        "prefix": "2001:db8:fff::",
                        "prefix-len": 48,
                        "delegated-len": 60
                    }
                ],
                "reservations": [
                    {
                        "hw-address": "52:54:00:d6:c2:a9",
                        "ip-addresses": [ "2001:db8::5054:ff:fed6:c2a9" ]
                    }
                ]
            }
        ]
    }
}

Starting Kea with this configuration was rather simple:

Starting Kea

$ kea-dhcp6 -c /etc/kea.json -d

Logs

When it starts you see some interesting bits in the log:

DHCP6_CONFIG_NEW_SUBNET a new subnet has been added to configuration: 2001:db8::/64 with params t1=1000, t2=2000, preferred-lifetime=3000, valid-lifetime=4000, rapid-commit is disabled
DHCPSRV_CFGMGR_ADD_SUBNET6 adding subnet 2001:db8::/64
HOSTS_CFG_ADD_HOST add the host for reservations: hwaddr=52:54:00:d6:c2:a9 ipv6_subnet_id=1024 hostname=(empty) ipv4_reservation=(no) ipv6_reservation0=2001:db8::5054:ff:fed6:c2a9
HOSTS_CFG_GET_ONE_SUBNET_ID_HWADDR_DUID get one host with IPv6 reservation for subnet id 1024, HWADDR hwtype=1 52:54:00:d6:c2:a9, DUID (no-duid)
HOSTS_CFG_GET_ALL_HWADDR_DUID get all hosts with reservations for HWADDR hwtype=1 52:54:00:d6:c2:a9 and DUID (no-duid)
HOSTS_CFG_GET_ALL_IDENTIFIER get all hosts with reservations using identifier: hwaddr=52:54:00:d6:c2:a9
HOSTS_CFG_GET_ALL_IDENTIFIER_COUNT using identifier hwaddr=52:54:00:d6:c2:a9, found 0 host(s)
HOSTS_CFG_GET_ONE_SUBNET_ID_HWADDR_DUID_NULL host not found using subnet id 1024, HW address hwtype=1 52:54:00:d6:c2:a9 and DUID (no-duid)
HOSTS_CFG_GET_ONE_SUBNET_ID_ADDRESS6 get one host with reservation for subnet id 1024 and including IPv6 address 2001:db8::5054:ff:fed6:c2a9
HOSTS_CFG_GET_ALL_SUBNET_ID_ADDRESS6 get all hosts with reservations for subnet id 1024 and IPv6 address 2001:db8::5054:ff:fed6:c2a9
HOSTS_CFG_GET_ALL_SUBNET_ID_ADDRESS6_COUNT using subnet id 1024 and address 2001:db8::5054:ff:fed6:c2a9, found 0 host(s)
HOSTS_CFG_GET_ONE_SUBNET_ID_ADDRESS6_NULL host not found using subnet id 1024 and address 2001:db8::5054:ff:fed6:c2a9
DHCPSRV_MEMFILE_DB opening memory file lease database: lfc-interval=1800 name=/tmp/kea-leases6.csv persist=true type=memfile universe=6
DHCPSRV_MEMFILE_LEASE_FILE_LOAD loading leases from file /tmp/kea-leases6.csv

You can see it has one reservation based on the MAC-address of the client which it handed out after it booted:

ALLOC_ENGINE_V6_HR_ADDR_GRANTED reserved address 2001:db8::5054:ff:fed6:c2a9 was assigned to client duid=[00:01:00:01:1e:47:7e:66:52:54:00:d6:c2:a9], tid=0xe7899a

Ubuntu client

The client was a simple Ubuntu 14.04 client with this network configuration:

auto eth0
iface eth0 inet dhcp
iface eth0 inet6 dhcp

And indeed, it obtained the correct address:

root@ubuntu1404:~# ip addr show dev eth0
2: eth0:  mtu 1500 qdisc pfifo_fast state UP group default qlen 1000
    link/ether 52:54:00:d6:c2:a9 brd ff:ff:ff:ff:ff:ff
    inet 192.168.100.100/24 brd 192.168.100.255 scope global eth0
       valid_lft forever preferred_lft forever
    inet6 2001:db8::5054:ff:fed6:c2a9/64 scope global deprecated dynamic 
       valid_lft 62sec preferred_lft 0sec
    inet6 fe80::5054:ff:fed6:c2a9/64 scope link 
       valid_lft forever preferred_lft forever
root@ubuntu1404:~#

Lease database

Kea can store the leases in a CSV file or MySQL database if you want. In this test I used /tmp/kea-leases6.csv as a CSV file to store the leases in.

In production a MySQL database is probably easier to use, but for the test CSV worked just fine.

Rebuilding libvirt under CentOS 7.1 with RBD storage pool support

If you want to use CentOS 7.1 for your hypervisors with Apache CloudStack and Ceph’s RBD as Primary Storage you need to rebuild libvirt.

CloudStack requires libvirt to be built with RBD storage pool support. It uses libvirt to manage RBD volumes. By default libvirt under CentOS is not built with this support. (On Ubuntu it is btw).

Rebuilding from source

First we need to install a couple of packages:

$ yum install -y rpm-build gcc make ceph-devel

Now we need to download the sRPM:

$ wget http://vault.centos.org/centos/7.1.1503/os/Source/SPackages/libvirt-1.2.8-16.el7.src.rpm

Create a rpmbuild directory:

$ mkdir /root/rpmbuild

Now edit /root/.rpmmacros so that it contains:

%_topdir    /root/rpmbuild

Install the sRPM:

$ rpm -i libvirt-1.2.8-16.el7.src.rpm

Open the /root/rpmbuild/SPECS/libvirt.spec file and look for:

%else
    %define with_storage_rbd      0
%endif

Change this to:

%else
    %define with_storage_rbd      1
%endif

Now build the RPM:

$ cd /root/rpmbuild
$ rpmbuild -ba SPECS/libvirt.spec

After a couple of minutes you should have RPMs with RBD storage pool support enabled!

Enhanced RBD support for CloudStack 4.2

About 1 hour ago the new storage subsystem got merged into the master branch of CloudStack. That is wonderful news for all you out there who want to use features like snapshotting with RBD in CloudStack.

In pre-4.2 CloudStack a snapshot was the same as a backup. As soon as you created a snapshot it would also copy that snapshot to the secondary storage. This could not only lead to high network utilization when talking about 1TB RBD volumes, but it also caused problems with the underlying ‘qemu-img’ tool. To make a long story short: Snapshots with RBD just wouldn’t work in CloudStack 4.0 or 4.1 without resorting to dirty hacking. Which we didn’t.

The new storage subsystem separates the backup and snapshot process. Snapshots are handled by the primary storage and they can be copied to the ‘backup storage’ on request. This allows is to use the full snapshot potential of RBD.

I was waiting for the storage subsystem to be merged into the master branch before I could start working on this. About two weeks ago I already wrote a small function spec in CloudStack’s wiki to describe what has to be done.

A couple of choices still have to be made. Traditionally we could do everything through libvirt and ‘qemu-img’, but from what I can see now we’ll run into some trouble. We might have to go through the process of wrapping librbd into a Java library to get it all done, but I’m not completely positive about that. Some patches for libvirt(-java) could probably also do the job, but it would take a lot of time and work to get those upstream and into the repositories. The goal is to have this new RBD code work natively on a Ubuntu 13.04 system.

The expectation is that CloudStack 4.2 will be released mid-July this year, but if you are a daredevil you can always track the master branch and play around with that.

I’ll post updates on the cloudstack-dev list on a regular base about the progress, but you can also watch the master branch and search for commits with ‘RBD’ in the message.