Documents Ganeti version 2.10
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Currently in Ganeti the admin has to specify the exact locations for an instance’s node(s). This prevents a completely automatic node evacuation, and is in general a nuisance.
The iallocator framework will enable automatic placement via external scripts, which allows customization of the cluster layout per the site’s requirements.
There are two parts of the ganeti operation that are impacted by the auto-allocation: how the cluster knows what the allocator algorithms are and how the admin uses these in creating instances.
An allocation algorithm is just the filename of a program installed in a defined list of directories.
At configure time, the list of the directories can be selected via the --with-iallocator-search-path=LIST option, where LIST is a comma-separated list of directories. If not given, this defaults to $libdir/ganeti/iallocators, i.e. for an installation under /usr, this will be /usr/lib/ganeti/iallocators.
Ganeti will then search for allocator script in the configured list, using the first one whose filename matches the one given by the user.
The node selection options in instance add and instance replace disks can be replace by the new --iallocator=NAME option (shortened to -I), which will cause the auto-assignement of nodes with the passed iallocator. The selected node(s) will be shown as part of the command output.
The protocol for communication between Ganeti and an allocator script will be the following:
The input message will be the JSON encoding of a dictionary containing all the required information to perform the operation. We explain the contents of this dictionary in two parts: common information that every type of operation requires, and operation-specific information.
All input dictionaries to the IAllocator must carry the following keys:
a dictionary with the data for the cluster’s node groups; it is keyed on the group UUID, and the values are a dictionary with the following keys:
a dictionary with the data for the current existing instance on the cluster, indexed by instance name; the contents are similar to the instance definitions for the allocate mode, with the addition of:
dictionary with the data for the nodes in the cluster, indexed by the node name; the dict contains [*] :
No allocations should be made on nodes having either the drained or offline flags set. More details about these of node status flags is available in the manpage ganeti(7).
[*] | Note that no run-time data is present for offline, drained or non-vm_capable nodes; this means the tags total_memory, reserved_memory, free_memory, total_disk, free_disk, total_cpus, i_pri_memory and i_pri_up memory will be absent |
All input dictionaries to the IAllocator carry, in the request dictionary, detailed information about the operation that’s being requested. The required keys vary depending on the type of operation, as follows.
In all cases, it includes:
- type
the request type; this can be either allocate, relocate, change-group or node-evacuate. The allocate request is used when a new instance needs to be placed on the cluster. The relocate request is used when an existing instance needs to be moved within its node group.
The multi-evacuate protocol used to request that the script computes the optimal relocate solution for all secondary instances of the given nodes. It is now deprecated and needs only be implemented if backwards compatibility with Ganeti 2.4 and lower is needed.
The change-group request is used to relocate multiple instances across multiple node groups. node-evacuate evacuates instances off their node(s). These are described in a separate design document.
The multi-allocate request is used to allocate multiple instances on the cluster. The request is beside of that very similiar to the allocate one. For more details look at Ganeti bulk create.
For both allocate and relocate mode, the following extra keys are needed in the request dictionary:
- name
- the name of the instance; if the request is a realocation, then this name will be found in the list of instances (see below), otherwise is the FQDN of the new instance; type string
- required_nodes
- how many nodes should the algorithm return; while this information can be deduced from the instace’s disk template, it’s better if this computation is left to Ganeti as then allocator scripts are less sensitive to changes to the disk templates; type integer
- disk_space_total
- the total disk space that will be used by this instance on the (new) nodes; again, this information can be computed from the list of instance disks and its template type, but Ganeti is better suited to compute it; type integer
Allocation needs, in addition:
- disks
list of dictionaries holding the disk definitions for this instance (in the order they are exported to the hypervisor):
- mode
- either ro or rw denoting if the disk is read-only or writable
- size
- the size of this disk in mebibytes
- nics
a list of dictionaries holding the network interfaces for this instance, containing:
- ip
- the IP address that Ganeti know for this instance, or null
- mac
- the MAC address for this interface
- bridge
- the bridge to which this interface will be connected
- vcpus
- the number of VCPUs for the instance
- disk_template
- the disk template for the instance
- memory
- the memory size for the instance
- os
- the OS type for the instance
- tags
- the list of the instance’s tags
- hypervisor
- the hypervisor of this instance
Relocation:
- relocate_from
- a list of nodes to move the instance away from; for DRBD-based instances, this will contain a single node, the current secondary of the instance, whereas for shared-storage instance, this will contain also a single node, the current primary of the instance; type list of strings
As for node-evacuate, it needs the following request arguments:
- instances
- a list of instance names to evacuate; type list of strings
- evac_mode
- specify which instances to evacuate; one of primary-only, secondary-only, all, type string
change-group needs the following request arguments:
- instances
- a list of instance names whose group to change; type list of strings
- target_groups
- must either be the empty list, or contain a list of group UUIDs that should be considered for relocating instances to; type list of strings
multi-allocate needs the following request arguments:
- instances
- a list of request dicts
Additional information is available from mond. Mond’s data collectors provide information that can help an allocator script make better decisions when allocating a new instance. Mond’s information may also be accessible from a mock file mainly for testing purposes. The file will be in JSON format and will present an array of report objects.
The response message is much more simple than the input one. It is also a dict having three keys:
the output of the algorithm; even if the algorithm failed (i.e. success is false), this must be returned as an empty list
for allocate/relocate, this is the list of node(s) for the instance; note that the length of this list must equal the requested_nodes entry in the input message, otherwise Ganeti will consider the result as failed
for the node-evacuate and change-group modes, this is a dictionary containing, among other information, a list of lists of serialized opcodes; see the design document for a detailed description
for the multi-allocate mode this is a tuple of 2 lists, the first being element of the tuple is a list of succeeded allocation, with the instance name as first element of each entry and the node placement in the second. The second element of the tuple is the instance list of failed allocations.
Note
Current Ganeti version accepts either result or nodes as a backwards-compatibility measure (older versions only supported nodes)
Input message, new instance allocation (common elements are listed this time, but not included in further examples below):
{
"version": 2,
"cluster_name": "cluster1.example.com",
"cluster_tags": [],
"enabled_hypervisors": [
"xen-pvm"
],
"nodegroups": {
"f4e06e0d-528a-4963-a5ad-10f3e114232d": {
"name": "default",
"alloc_policy": "preferred",
"networks": ["net-uuid-1", "net-uuid-2"],
"ipolicy": {
"disk-templates": ["drbd", "plain"],
"minmax": [
{
"max": {
"cpu-count": 2,
"disk-count": 8,
"disk-size": 2048,
"memory-size": 12800,
"nic-count": 8,
"spindle-use": 8
},
"min": {
"cpu-count": 1,
"disk-count": 1,
"disk-size": 1024,
"memory-size": 128,
"nic-count": 1,
"spindle-use": 1
}
}
],
"spindle-ratio": 32.0,
"std": {
"cpu-count": 1,
"disk-count": 1,
"disk-size": 1024,
"memory-size": 128,
"nic-count": 1,
"spindle-use": 1
},
"vcpu-ratio": 4.0
},
"tags": ["ng-tag-1", "ng-tag-2"]
}
},
"instances": {
"instance1.example.com": {
"tags": [],
"should_run": false,
"disks": [
{
"mode": "w",
"size": 64
},
{
"mode": "w",
"size": 512
}
],
"nics": [
{
"ip": null,
"mac": "aa:00:00:00:60:bf",
"bridge": "xen-br0"
}
],
"vcpus": 1,
"disk_template": "plain",
"memory": 128,
"nodes": [
"nodee1.com"
],
"os": "debootstrap+default"
},
"instance2.example.com": {
"tags": [],
"should_run": false,
"disks": [
{
"mode": "w",
"size": 512
},
{
"mode": "w",
"size": 256
}
],
"nics": [
{
"ip": null,
"mac": "aa:00:00:55:f8:38",
"bridge": "xen-br0"
}
],
"vcpus": 1,
"disk_template": "drbd",
"memory": 512,
"nodes": [
"node2.example.com",
"node3.example.com"
],
"os": "debootstrap+default"
}
},
"nodes": {
"node1.example.com": {
"total_disk": 858276,
"primary_ip": "198.51.100.1",
"secondary_ip": "192.0.2.1",
"tags": [],
"group": "f4e06e0d-528a-4963-a5ad-10f3e114232d",
"free_memory": 3505,
"free_disk": 856740,
"total_memory": 4095
},
"node2.example.com": {
"total_disk": 858240,
"primary_ip": "198.51.100.2",
"secondary_ip": "192.0.2.2",
"tags": ["test"],
"group": "f4e06e0d-528a-4963-a5ad-10f3e114232d",
"free_memory": 3505,
"free_disk": 848320,
"total_memory": 4095
},
"node3.example.com.com": {
"total_disk": 572184,
"primary_ip": "198.51.100.3",
"secondary_ip": "192.0.2.3",
"tags": [],
"group": "f4e06e0d-528a-4963-a5ad-10f3e114232d",
"free_memory": 3505,
"free_disk": 570648,
"total_memory": 4095
}
},
"request": {
"type": "allocate",
"name": "instance3.example.com",
"required_nodes": 2,
"disk_space_total": 3328,
"disks": [
{
"mode": "w",
"size": 1024
},
{
"mode": "w",
"size": 2048
}
],
"nics": [
{
"ip": null,
"mac": "00:11:22:33:44:55",
"bridge": null
}
],
"vcpus": 1,
"disk_template": "drbd",
"memory": 2048,
"os": "debootstrap+default",
"tags": [
"type:test",
"owner:foo"
],
hypervisor: "xen-pvm"
}
}
Input message, reallocation:
{
"version": 2,
...
"request": {
"type": "relocate",
"name": "instance2.example.com",
"required_nodes": 1,
"disk_space_total": 832,
"relocate_from": [
"node3.example.com"
]
}
}
Successful response message:
{
"success": true,
"info": "Allocation successful",
"result": [
"node2.example.com",
"node1.example.com"
]
}
Failed response message:
{
"success": false,
"info": "Can't find a suitable node for position 2 (already selected: node2.example.com)",
"result": []
}
Successful node evacuation message:
{
"success": true,
"info": "Request successful",
"result": [
[
"instance1",
"node3"
],
[
"instance2",
"node1"
]
]
}
# gnt-instance add -t plain -m 2g --os-size 1g --swap-size 512m --iallocator hail -o debootstrap+default instance3
Selected nodes for the instance: node1.example.com
* creating instance disks...
[...]
# gnt-instance add -t plain -m 3400m --os-size 1g --swap-size 512m --iallocator hail -o debootstrap+default instance4
Failure: prerequisites not met for this operation:
Can't compute nodes using iallocator 'hail': Can't find a suitable node for position 1 (already selected: )
# gnt-instance add -t drbd -m 1400m --os-size 1g --swap-size 512m --iallocator hail -o debootstrap+default instance5
Failure: prerequisites not met for this operation:
Can't compute nodes using iallocator 'hail': Can't find a suitable node for position 2 (already selected: node1.example.com)
Ganeti’s default iallocator is “hail” which is available when “htools” components have been enabled at build time (see Ganeti quick installation guide for more details).