This document describes the major changes in Ganeti 2.2 compared to the 2.1 version.
The 2.2 version will be a relatively small release. Its main aim is to avoid changing too much of the core code, while addressing issues and adding new features and improvements over 2.1, in a timely fashion.
As for 2.1 we divide the 2.2 design into three areas:
Currently the Ganeti master daemon is based on four sets of threads:
This means that every masterd currently runs 52 threads to do its job. Being able to reduce the number of thread sets would make the master’s architecture a lot simpler. Moreover having less threads can help decrease lock contention, log pollution and memory usage. Also, with the current architecture, masterd suffers from quite a few scalability issues:
Since the 16 client worker threads handle one connection each, it’s very easy to exhaust them, by just connecting to masterd 16 times and not sending any data. While we could perhaps make those pools resizable, increasing the number of threads won’t help with lock contention nor with better handling long running operations making sure the client is informed that everything is proceeding, and doesn’t need to time out.
The REQ_WAIT_FOR_JOB_CHANGE luxi operation makes the relevant client thread block on its job for a relatively long time. This is another easy way to exhaust the 16 client threads, and a place where clients often time out, moreover this operation is negative for the job queue lock contention (see below).
The job queue lock is quite heavily contended, and certain easily reproducible workloads show that’s it’s very easy to put masterd in trouble: for example running ~15 background instance reinstall jobs, results in a master daemon that, even without having finished the client worker threads, can’t answer simple job list requests, or submit more jobs.
Currently the job queue lock is an exclusive non-fair lock insulating the following job queue methods (called by the client workers).
- AddNode
- RemoveNode
- SubmitJob
- SubmitManyJobs
- WaitForJobChanges
- CancelJob
- ArchiveJob
- AutoArchiveJobs
- QueryJobs
- Shutdown
Moreover the job queue lock is acquired outside of the job queue in two other classes:
- jqueue._JobQueueWorker (in RunTask) before executing the opcode, after finishing its executing and when handling an exception.
- jqueue._OpExecCallbacks (in NotifyStart and Feedback) when the processor (mcpu.Processor) is about to start working on the opcode (after acquiring the necessary locks) and when any data is sent back via the feedback function.
Of those the major critical points are:
- Submit[Many]Job, QueryJobs, WaitForJobChanges, which can easily slow down and block client threads up to making the respective clients time out.
- The code paths in NotifyStart, Feedback, and RunTask, which slow down job processing between clients and otherwise non-related jobs.
To increase the pain:
- WaitForJobChanges is a bad offender because it’s implemented with a notified condition which awakes waiting threads, who then try to acquire the global lock again
- Many should-be-fast code paths are slowed down by replicating the change to remote nodes, and thus waiting, with the lock held, on remote rpcs to complete (starting, finishing, and submitting jobs)
In order to be able to interact with the master daemon even when it’s under heavy load, and to make it simpler to add core functionality (such as an asynchronous rpc client) we propose three subsequent levels of changes to the master core architecture.
After making this change we’ll be able to re-evaluate the size of our thread pool, if we see that we can make most threads in the client worker pool always idle. In the future we should also investigate making the rpc client asynchronous as well, so that we can make masterd a lot smaller in number of threads, and memory size, and thus also easier to understand, debug, and scale.
We’ll move the main thread of ganeti-masterd to asyncore, so that it can share the mainloop code with all other Ganeti daemons. Then all luxi clients will be asyncore clients, and I/O to/from them will be handled by the master thread asynchronously. Data will be read from the client sockets as it becomes available, and kept in a buffer, then when a complete message is found, it’s passed to a client worker thread for parsing and processing. The client worker thread is responsible for serializing the reply, which can then be sent asynchronously by the main thread on the socket.
The REQ_WAIT_FOR_JOB_CHANGE luxi request is changed to be subscription-based, so that the executing thread doesn’t have to be waiting for the changes to arrive. Threads producing messages (job queue executors) will make sure that when there is a change another thread is awakened and delivers it to the waiting clients. This can be either a dedicated “wait for job changes” thread or pool, or one of the client workers, depending on what’s easier to implement. In either case the main asyncore thread will only be involved in pushing of the actual data, and not in fetching/serializing it.
Other features to look at, when implementing this code are:
- Possibility not to need the job lock to know which updates to push: if the thread producing the data pushed a copy of the update for the waiting clients, the thread sending it won’t need to acquire the lock again to fetch the actual data.
- Possibility to signal clients about to time out, when no update has been received, not to despair and to keep waiting (luxi level keepalive).
- Possibility to defer updates if they are too frequent, providing them at a maximum rate (lower priority).
In order to decrease the job queue lock contention, we will change the code paths in the following ways, initially:
- A per-job lock will be introduced. All operations affecting only one job (for example feedback, starting/finishing notifications, subscribing to or watching a job) will only require the job lock. This should be a leaf lock, but if a situation arises in which it must be acquired together with the global job queue lock the global one must always be acquired last (for the global section).
- The locks will be converted to a sharedlock. Any read-only operation will be able to proceed in parallel.
- During remote update (which happens already per-job) we’ll drop the job lock level to shared mode, so that activities reading the lock (for example job change notifications or QueryJobs calls) will be able to proceed in parallel.
- The wait for job changes improvements proposed above will be implemented.
In the future other improvements may include splitting off some of the work (eg replication of a job to remote nodes) to a separate thread pool or asynchronous thread, not tied with the code path for answering client requests or the one executing the “real” work. This can be discussed again after we used the more granular job queue in production and tested its benefits.
With the current design of Ganeti, moving whole instances between different clusters involves a lot of manual work. There are several ways to move instances, one of them being to export the instance, manually copying all data to the new cluster before importing it again. Manual changes to the instances configuration, such as the IP address, may be necessary in the new environment. The goal is to improve and automate this process in Ganeti 2.2.
Until now, each Ganeti cluster was a self-contained entity and wouldn’t talk to other Ganeti clusters. Nodes within clusters only had to trust the other nodes in the same cluster and the network used for replication was trusted, too (hence the ability the use a separate, local network for replication).
For inter-cluster instance transfers this model must be weakened. Nodes in one cluster will have to talk to nodes in other clusters, sometimes in other locations and, very important, via untrusted network connections.
Various option have been considered for securing and authenticating the data transfer from one machine to another. To reduce the risk of accidentally overwriting data due to software bugs, authenticating the arriving data was considered critical. Eventually we decided to use socat’s OpenSSL options (OPENSSL:, OPENSSL-LISTEN: et al), which provide us with encryption, authentication and authorization when used with separate keys and certificates.
Combinations of OpenSSH, GnuPG and Netcat were deemed too complex to set up from within Ganeti. Any solution involving OpenSSH would require a dedicated user with a home directory and likely automated modifications to the user’s $HOME/.ssh/authorized_keys file. When using Netcat, GnuPG or another encryption method would be necessary to transfer the data over an untrusted network. socat combines both in one program and is already a dependency.
Each of the two clusters will have to generate an RSA key. The public parts are exchanged between the clusters by a third party, such as an administrator or a system interacting with Ganeti via the remote API (“third party” from here on). After receiving each other’s public key, the clusters can start talking to each other.
All encrypted connections must be verified on both sides. Neither side may accept unverified certificates. The generated certificate should only be valid for the time necessary to move the instance.
For additional protection of the instance data, the two clusters can verify the certificates and destination information exchanged via the third party by checking an HMAC signature using a key shared among the involved clusters. By default this secret key will be a random string unique to the cluster, generated by running SHA1 over 20 bytes read from /dev/urandom and the administrator must synchronize the secrets between clusters before instances can be moved. If the third party does not know the secret, it can’t forge the certificates or redirect the data. Unless disabled by a new cluster parameter, verifying the HMAC signatures must be mandatory. The HMAC signature for X509 certificates will be prepended to the certificate similar to an RFC 822 header and only covers the certificate (from -----BEGIN CERTIFICATE----- to -----END CERTIFICATE-----). The header name will be X-Ganeti-Signature and its value will have the format $salt/$hash (salt and hash separated by slash). The salt may only contain characters in the range [a-zA-Z0-9].
On the web, the destination cluster would be equivalent to an HTTPS server requiring verifiable client certificates. The browser would be equivalent to the source cluster and must verify the server’s certificate while providing a client certificate to the server.
To simplify the implementation, we decided to operate at a block-device level only, allowing us to easily support non-DRBD instance moves.
Intra-cluster instance moves will re-use the existing export and import scripts supplied by instance OS definitions. Unlike simply copying the raw data, this allows one to use filesystem-specific utilities to dump only used parts of the disk and to exclude certain disks from the move. Compression should be used to further reduce the amount of data transferred.
The export scripts writes all data to stdout and the import script reads it from stdin again. To avoid copying data and reduce disk space consumption, everything is read from the disk and sent over the network directly, where it’ll be written to the new block device directly again.
The following pseudo code describes a script moving instances between clusters and what happens on both clusters.
Script is started, gets the instance name and destination cluster:
(instance_name, dest_cluster_name) = sys.argv[1:]
# Get destination cluster object
dest_cluster = db.FindCluster(dest_cluster_name)
# Use database to find source cluster
src_cluster = db.FindClusterByInstance(instance_name)
Script tells source cluster to stop instance:
# Stop instance
src_cluster.StopInstance(instance_name)
# Get instance specification (memory, disk, etc.)
inst_spec = src_cluster.GetInstanceInfo(instance_name)
(src_key_name, src_cert) = src_cluster.CreateX509Certificate()
CreateX509Certificate on source cluster:
key_file = mkstemp()
cert_file = "%s.cert" % key_file
RunCmd(["/usr/bin/openssl", "req", "-new",
"-newkey", "rsa:1024", "-days", "1",
"-nodes", "-x509", "-batch",
"-keyout", key_file, "-out", cert_file])
plain_cert = utils.ReadFile(cert_file)
# HMAC sign using secret key, this adds a "X-Ganeti-Signature"
# header to the beginning of the certificate
signed_cert = utils.SignX509Certificate(plain_cert,
utils.ReadFile(constants.X509_SIGNKEY_FILE))
# The certificate now looks like the following:
#
# X-Ganeti-Signature: $1234$28676f0516c6ab68062b[…]
# -----BEGIN CERTIFICATE-----
# MIICsDCCAhmgAwIBAgI[…]
# -----END CERTIFICATE-----
# Return name of key file and signed certificate in PEM format
return (os.path.basename(key_file), signed_cert)
Script creates instance on destination cluster and waits for move to finish:
dest_cluster.CreateInstance(mode=constants.REMOTE_IMPORT,
spec=inst_spec,
source_cert=src_cert)
# Wait until destination cluster gives us its certificate
dest_cert = None
disk_info = []
while not (dest_cert and len(disk_info) < len(inst_spec.disks)):
tmp = dest_cluster.WaitOutput()
if tmp is Certificate:
dest_cert = tmp
elif tmp is DiskInfo:
# DiskInfo contains destination address and port
disk_info[tmp.index] = tmp
# Tell source cluster to export disks
for disk in disk_info:
src_cluster.ExportDisk(instance_name, disk=disk,
key_name=src_key_name,
dest_cert=dest_cert)
print ("Instance %s sucessfully moved to %s" %
(instance_name, dest_cluster.name))
CreateInstance on destination cluster:
# …
if mode == constants.REMOTE_IMPORT:
# Make sure certificate was not modified since it was generated by
# source cluster (which must use the same secret)
if (not utils.VerifySignedX509Cert(source_cert,
utils.ReadFile(constants.X509_SIGNKEY_FILE))):
raise Error("Certificate not signed with this cluster's secret")
if utils.CheckExpiredX509Cert(source_cert):
raise Error("X509 certificate is expired")
source_cert_file = utils.WriteTempFile(source_cert)
# See above for X509 certificate generation and signing
(key_name, signed_cert) = CreateSignedX509Certificate()
SendToClient("x509-cert", signed_cert)
for disk in instance.disks:
# Start socat
RunCmd(("socat"
" OPENSSL-LISTEN:%s,…,key=%s,cert=%s,cafile=%s,verify=1"
" stdout > /dev/disk…") %
port, GetRsaKeyPath(key_name, private=True),
GetRsaKeyPath(key_name, private=False), src_cert_file)
SendToClient("send-disk-to", disk, ip_address, port)
DestroyX509Cert(key_name)
RunRenameScript(instance_name)
ExportDisk on source cluster:
# Make sure certificate was not modified since it was generated by
# destination cluster (which must use the same secret)
if (not utils.VerifySignedX509Cert(cert_pem,
utils.ReadFile(constants.X509_SIGNKEY_FILE))):
raise Error("Certificate not signed with this cluster's secret")
if utils.CheckExpiredX509Cert(cert_pem):
raise Error("X509 certificate is expired")
dest_cert_file = utils.WriteTempFile(cert_pem)
# Start socat
RunCmd(("socat stdin"
" OPENSSL:%s:%s,…,key=%s,cert=%s,cafile=%s,verify=1"
" < /dev/disk…") %
disk.host, disk.port,
GetRsaKeyPath(key_name, private=True),
GetRsaKeyPath(key_name, private=False), dest_cert_file)
if instance.all_disks_done:
DestroyX509Cert(key_name)
All Ganeti daemons are run under the user root. This is not ideal from a security perspective as for possible exploitation of any daemon the user has full access to the system.
In order to overcome this situation we’ll allow Ganeti to run its daemon under different users and a dedicated group. This also will allow some side effects, like letting the user run some gnt-* commands if one is in the same group.
For Ganeti 2.2 the implementation will be focused on a the RAPI daemon only. This involves changes to daemons.py so it’s possible to drop privileges on daemonize the process. Though, this will be a short term solution which will be replaced by a privilege drop already on daemon startup in Ganeti 2.3.
It also needs changes in the master daemon to create the socket with new permissions/owners to allow RAPI access. There will be no other permission/owner changes in the file structure as the RAPI daemon is started with root permission. In that time it will read all needed files and then drop privileges before contacting the master daemon.
Currently all kvm processes run as root. Taking ownership of the hypervisor process, from inside a virtual machine, would mean a full compromise of the whole Ganeti cluster, knowledge of all Ganeti authentication secrets, full access to all running instances, and the option of subverting other basic services on the cluster (eg: ssh).
We would like to decrease the surface of attack available if an hypervisor is compromised. We can do so adding different features to Ganeti, which will allow restricting the broken hypervisor possibilities, in the absence of a local privilege escalation attack, to subvert the node.
By passing the -runas option to kvm, we can make it drop privileges. The user can be chosen by an hypervisor parameter, so that each instance can have its own user, but by default they will all run under the same one. It should be very easy to implement, and can easily be backported to 2.1.X.
This mode protects the Ganeti cluster from a subverted hypervisor, but doesn’t protect the instances between each other, unless care is taken to specify a different user for each. This would prevent the worst attacks, including:
But the following would remain an option:
By passing the -chroot option to kvm, we can restrict the kvm process in its own (possibly empty) root directory. We need to set this area up so that the instance disks and control sockets are accessible, so it would require slightly more work at the Ganeti level.
Breaking out in a chroot would mean:
It would still be possible though to:
If rather than passing a single user as an hypervisor parameter, we have a pool of useable ones, we can dynamically choose a free one to use and thus guarantee that each machine will be separate from the others, without putting the burden of this on the cluster administrator.
This would mean interfering between machines would be impossible, and can still be combined with the chroot benefits.
These don’t need to be handled by Ganeti, but we can ship examples. If the users used to run VMs would be blocked from sending some or all network traffic, it would become impossible for a broken into hypervisor to send arbitrary data on the node network, which is especially useful when the instance and the node network are separated (using ganeti-nbma or a separate set of network interfaces), or when a separate replication network is maintained. We need to experiment to see how much restriction we can properly apply, without limiting the instance legitimate traffic.
Recent linux kernels support different process namespaces through control groups. PIDs, users, filesystems and even network interfaces can be separated. If we can set up ganeti to run kvm in a separate container we could insulate all the host process from being even visible if the hypervisor gets broken into. Most probably separating the network namespace would require one extra hop in the host, through a veth interface, thus reducing performance, so we may want to avoid that, and just rely on iptables.
We will first implement dropping privileges for kvm processes as a single user, and most probably backport it to 2.1. Then we’ll ship example iptables rules to show how the user can be limited in its network activities. After that we’ll implement chroot restriction for kvm processes, and extend the user limitation to use a user pool.
Finally we’ll look into namespaces and containers, although that might slip after the 2.2 release.
Separate from the OS external changes, described below, we’ll add some internal changes to the OS.
There are two issues related to the handling of the OSes.
First, it’s impossible to disable an OS for new instances, since that will also break reinstallations and renames of existing instances. To phase out an OS definition, without actually having to modify the OS scripts, it would be ideal to be able to restrict new installations but keep the rest of the functionality available.
Second, gnt-instance reinstall --select-os shows all the OSes available on the clusters. Some OSes might exist only for debugging and diagnose, and not for end-user availability. For this, it would be useful to “hide” a set of OSes, but keep it otherwise functional.
Two new cluster-level attributes will be added, holding the list of OSes hidden from the user and respectively the list of OSes which are blacklisted from new installations.
These lists will be modifiable via gnt-os modify (implemented via OpClusterSetParams), such that even not-yet-existing OSes can be preseeded into a given state.
For the hidden OSes, they are fully functional except that they are not returned in the default OS list (as computed via OpOsDiagnose), unless the hidden state is requested.
For the blacklisted OSes, they are also not shown (unless the blacklisted state is requested), and they are also prevented from installation via OpInstanceCreate (in create mode).
Both these attributes are per-OS, not per-variant. Thus they apply to all of an OS’ variants, and it’s impossible to blacklist or hide just one variant. Further improvements might allow a given OS variant to be blacklisted, as opposed to whole OSes.
The OS variants implementation in Ganeti 2.1 didn’t prove to be useful enough to alleviate the need to hack around the Ganeti API in order to provide flexible OS parameters.
As such, for Ganeti 2.2 we will provide support for arbitrary OS parameters. However, since OSes are not registered in Ganeti, but instead discovered at runtime, the interface is not entirely straightforward.
Furthermore, to support the system administrator in keeping OSes properly in sync across the nodes of a cluster, Ganeti will also verify (if existing) the consistence of a new os_version file.
These changes to the OS API will bump the API version to 20.
A new os_version file will be supported by Ganeti. This file is not required, but if existing, its contents will be checked for consistency across nodes. The file should hold only one line of text (any extra data will be discarded), and its contents will be shown in the OS information and diagnose commands.
It is recommended that OS authors increase the contents of this file for any changes; at a minimum, modifications that change the behaviour of import/export scripts must increase the version, since they break intra-cluster migration.
The interface between Ganeti and the OS scripts will be based on environment variables, and as such the parameters and their values will need to be valid in this context.
The parameter names will be declared in a new file, parameters.list, together with a one-line documentation (whitespace-separated). Example:
$ cat parameters.list
ns1 Specifies the first name server to add to /etc/resolv.conf
extra_packages Specifies additional packages to install
rootfs_size Specifies the root filesystem size (the rest will be left unallocated)
track Specifies the distribution track, one of 'stable', 'testing' or 'unstable'
As seen above, the documentation can be separate via multiple spaces/tabs from the names.
The parameter names as read from the file will be used for the command line interface in lowercased form; as such, there shouldn’t be any two parameters which differ in case only.
The values of the parameters are, from Ganeti’s point of view, completely freeform. If a given parameter has, from the OS’ point of view, a fixed set of valid values, these should be documented as such and verified by the OS, but Ganeti will not handle such parameters specially.
An empty value must be handled identically as a missing parameter. In other words, the validation script should only test for non-empty values, and not for declared versus undeclared parameters.
Furthermore, each parameter should have an (internal to the OS) default value, that will be used if not passed from Ganeti. More precisely, it should be possible for any parameter to specify a value that will have the same effect as not passing the parameter, and no in no case should the absence of a parameter be treated as an exceptional case (outside the value space).
The parameters will be exposed in the environment upper-case and prefixed with the string OSP_. For example, a parameter declared in the ‘parameters’ file as ns1 will appear in the environment as the variable OSP_NS1.
For the purpose of parameter name/value validation, the OS scripts must provide an additional script, named verify. This script will be called with the argument parameters, and all the parameters will be passed in via environment variables, as described above.
The script should signify result/failure based on its exit code, and show explanatory messages either on its standard output or standard error. These messages will be passed on to the master, and stored as in the OpCode result/error message.
The parameters must be constructed to be independent of the instance specifications. In general, the validation script will only be called with the parameter variables set, but not with the normal per-instance variables, in order for Ganeti to be able to validate default parameters too, when they change. Validation will only be performed on one cluster node, and it will be up to the ganeti administrator to keep the OS scripts in sync between all nodes.
The parameters will be passed, as described above, to all the other instance operations (creation, import, export). Ideally, these scripts will not abort with parameter validation errors, if the verify script has verified them correctly.
Note: when changing an instance’s OS type, any OS parameters defined at instance level will be kept as-is. If the parameters differ between the new and the old OS, the user should manually remove/update them as needed.
Since the OSes are not registered in Ganeti, we will only make a ‘weak’ link between the parameters as declared in Ganeti and the actual OSes existing on the cluster.
It will be possible to declare parameters either globally, per cluster (where they are indexed per OS/variant), or individually, per instance. The declaration of parameters will not be tied to current existing OSes. When specifying a parameter, if the OS exists, it will be validated; if not, then it will simply be stored as-is.
A special note is that it will not be possible to ‘unset’ at instance level a parameter that is declared globally. Instead, at instance level the parameter should be given an explicit value, or the default value as explained above.
The modification of global (default) parameters will be done via the gnt-os command, and the per-instance parameters via the gnt-instance command. Both these commands will take an addition --os-parameters or -O flag that specifies the parameters in the familiar comma-separated, key=value format. For removing a parameter, a -key syntax will be used, e.g.:
# initial modification
$ gnt-instance modify -O use_dchp=true instance1
# later revert (to the cluster default, or the OS default if not
# defined at cluster level)
$ gnt-instance modify -O -use_dhcp instance1
Internally, the OS parameters will be stored in a new osparams attribute. The global parameters will be stored on the cluster object, and the value of this attribute will be a dictionary indexed by OS name (this also accepts an OS+variant name, which will override a simple OS name, see below), and for values the key/name dictionary. For the instances, the value will be directly the key/name dictionary.
Any instance-specific parameters will override any variant-specific parameters, which in turn will override any global parameters. The global parameters, in turn, override the built-in defaults (of the OS scripts).