16 KiB
Divingbell
Divingbell is a lightweight solution for:
- Bare metal configuration management for a few very targeted use cases
- Bare metal package manager orchestration
What problems does it solve?
The needs identified for Divingbell were:
- To plug gaps in day 1 tools (e.g., Drydock) for node configuration
- To provide a day 2 solution for managing these configurations going forward
- [Future] To provide a day 2 solution for system level host patching
Design and Implementation
Divingbell daemonsets run as privileged containers which mount the host filesystem and chroot into that filesystem to enforce configuration and package state. (The diving bell analogue can be thought of as something that descends into the deeps to facilitate work done down below the surface.)
We use the daemonset construct as a way of getting a copy of each pod on every node, but the work done by this chart's pods behaves like an event-driven job. In practice this means that the chart internals run once on pod startup, followed by an infinite sleep such that the pods always report a "Running" status that k8s recognizes as the healthy (expected) result for a daemonset.
In order to keep configuration as isolated as possible from other systems that manage common files like /etc/fstab and /etc/sysctl.conf, Divingbell daemonsets manage all of their configuration in separate files (e.g. by writing unique files to /etc/sysctl.d or defining unique Systemd units) to avoid potential conflicts. Another example is limit management, Divingbell daemonset writes separate files to /etc/security/limits.d.
To maximize robustness and utility, the daemonsets in this chart are made to be idempotent. In addition, they are designed to implicitly restore the original system state after previously defined states are undefined. (e.g., removing a previously defined mount from the yaml manifest, with no record of the original mount in the updated manifest).
Lifecycle management
This chart's daemonsets will be spawned by Armada. They run in an event-driven fashion: the idempotent automation for each daemonset will only re-run when Armada spawns/respawns the container, or if information relevant to the host changes in the configmap.
Daemonset configs
sysctl
Used to manage host level sysctl tunables. Ex:
conf:
sysctl:
net/ipv4/ip_forward: 1
net/ipv6/conf/all/forwarding: 1limits
Used to manage host level limits. Ex:
conf:
limits:
nofile:
domain: 'root'
type: 'soft'
item: 'nofile'
value: '101'
core_dump:
domain: '0:'
type: 'hard'
item: 'core'
value: 0Previous values of newly set limits are backed up to /var/divingbell/limits
mounts
used to manage host level mounts (outside of those in /etc/fstab). Ex:
conf:
mounts:
mnt:
mnt_tgt: /mnt
device: tmpfs
type: tmpfs
options: 'defaults,noatime,nosuid,nodev,noexec,mode=1777,size=1024M'ethtool
Used to manage host level NIC tunables. Ex:
conf:
ethtool:
ens3:
tx-tcp-segmentation: off
tx-checksum-ip-generic: onuamlite
Used to manage host level local user accounts, their SSH keys, and their sudo access. Ex:
conf:
uamlite:
purge_expired_users: false
users:
- user_name: testuser
user_crypt_passwd: $6$...
user_sudo: true
user_sshkeys:
- ssh-rsa AAAAB3N... key1-comment
- ssh-rsa AAAAVY6... key2-commentapt
apt daemonset does package management. It is able to
install a package of a specific version (or upgrade an existing one to
requested version). Version is optional, and if not provided the latest
available package is installed. It can also remove packages that were
previously installed by divingbell (it is done by excluding the packages
you want to remove from the configuration). Here is an example
configuration for it:
conf:
apt:
packages:
- name: <PACKAGE1>
version: <VERSION1>
- name: <PACKAGE2>It is also possible to provide debconf settings for packages the following way:
conf:
apt:
packages:
- name: openssh-server
debconf:
- question: openssh-server/permit-root-login
question_type: boolean
answer: falseexec
Used to execute scripts on nodes, ex:
exec:
002-script2.sh:
data: |
#!/bin/bash
echo ${BASH_SOURCE}
001-script1.sh:
blocking_policy: foreground_halt_pod_on_failure
env:
env1: env1-val
env2: env2-val
args:
- arg1
- arg2
data: |
#!/bin/bash
echo script name: ${BASH_SOURCE}
echo args: $@
echo env: $env1 $env2 $env3Scripts are executed in alphanumeric order with the key names used. Therefore in this example, 001-script1.sh runs first, followed by 002-script2.sh. Targeting of directives to specific nodes by hostname or node label is achievable by use of the overrides capability described below.
The following set of options are fully implemeneted:
``rerun_policy`` may be optionally set to ``always``, ``never``, or
``once_successfully`` for a given script. That script would always be rerun,
never be rerun, or rerun until the first successful execution respectively.
Default value is ``always``. This is tracked via a hash of the dict object
for the script (i.e. script name, script data, script args, script env, etc).
If any of that info changes, so will the hash, and it will be seen as a new
object which will be executed regardless of this setting.
``script_timeout`` may optionally be set to the number of seconds to wait for
script completion before termination. Default value is ``1800`` (30 min).
``rerun_interval`` may be optionally set to the number of seconds to wait
between rerunning a given script which ran successfully the previous time.
Default value is ``infinite``.
``retry_interval`` may be optionally set to the number of seconds to wait
between rerunning a given script which did not run successfully the previous
time. Default behavior is to match the ``rerun_interval``.The following set of options are partially implemeneted:
``blocking_policy`` may optionally be set to ``background``, ``foreground``,
or ``foreground_halt_pod_on_failure`` for a given script. This may be used to
run a script in the background (running in parallel, i.e. non-blocking) or
in the foreground (blocking). In either case, a failure of the script does
not cause a failure (crashloop) of the pod. The third option may be used
where the reverse behavior is desired (i.e., it would not proceed with
running the next script in the sequence until the current script ran
successfully). ``background`` option is not yet implemeneted. Default value
Deafult value is ``foreground``.The following set of options are not yet implemeneted:
``rerun_interval_persist`` may be optionally set to ``false`` for a given
script. This makes the script execute on pod/node startup regardless of the
interval since the last successful execution. Default value is ``true``.
``rerun_max_count`` may be optionally set to the maximum number of times a
succeeding script should be retried. Successful exec count does not persist
through pod/node restart. Default value is ``infinite``.
``retry_interval_persist`` may be optionally set to ``false`` for a given
script. This makes the script execute on pod/node startup, regardless of the
time since the last execution. Default value is ``true``.
``retry_max_count`` may be optionally set to the maximum number of times a
failing script should be retried. Failed exec count does not persist
through pod/node restart. Default value is ``infinite``.apparmor
Used to manage host level apparmor profiles/rules, Ex:
conf:
apparmor:
complain_mode: "true"
profiles:
profile-1: |
#include <tunables/global>
/usr/sbin/profile-1 {
#include <abstractions/apache2-common>
#include <abstractions/base>
#include <abstractions/nis>
capability dac_override,
capability dac_read_search,
capability net_bind_service,
capability setgid,
capability setuid,
/data/www/safe/* r,
deny /data/www/unsafe/* r,
}
profile-2: |
#include <tunables/global>
/usr/sbin/profile-2 {
#include <abstractions/apache2-common>
#include <abstractions/base>
#include <abstractions/nis>
capability dac_override,
capability dac_read_search,
capability net_bind_service,
capability setgid,
capability setuid,
/data/www/safe/* r,
deny /data/www/unsafe/* r,
}Operations
Setting apparmor profiles
The way apparmor loading/unloading implemented is through saving
settings to a file and than running apparmor_parser
command. The daemonset supports both enforcement and complain mode,
enforcement being the default. To request complain mode for the
profiles, add complain_mode: "true" nested under apparmor
entry.
It's easy to mess up host with rules, if profile names would distinguish from file content. Ex:
conf:
apparmor:
profiles:
profile-1: |
#include <tunables/global>
/usr/sbin/profile-1 {
#include <abstractions/base>
capability setgid,
}
profile-2: |
#include <tunables/global>
/usr/sbin/profile-1 {
#include <abstractions/base>
capability net_bind_service,
}Even when profiles are different (profile-1 vs profile-2) - filenames are the same (profile-1), that means that only one set of rules in memory would be active for particular profile (either setgid or net_bind_service), but not both. Such problems are hard to debug, so caution needed while setting configs up.
Setting user passwords
Including user_crypt_passwd to set a user password is
optional.
If setting a password for the user, the chart expects the password to
be encrypted with SHA-512 and formatted in the way that
crypt library expects. Run the following command to
generate the needed encrypted password from the plaintext password:
python3 -c "from getpass import getpass; from crypt import *; p=getpass(); print('\n'+crypt(p, METHOD_SHA512)) if p==getpass('Please repeat: ') else print('\nPassword mismatch.')"Use the output of the above command as the
user_crypt_passwd for the user. (Credit to unix.stackexchange.com.)
If the password is not formatted how crypt expects, the chart will throw
an error and fail to render.
At least one user must be defined with a password and sudo in order
for the built-in ubuntu account to be disabled. This is
because in a situation where network access is unavailable, console
username/password access will be the only login option.
Setting user sudo
Including user_sudo to set user sudo access is optional.
The default value is false.
At least one user must be defined with sudo access in order for the
built-in ubuntu account to be disabled.
SSH keys
Including user_sshkeys for defining one or more user SSH
keys is optional.
The chart will throw an error and fail to render if the SSH key is not one of the following formats:
- dsa (ssh-dss ...)
- ecdsa (ecdsa-...)
- ed25519 (ssh-ed25519 ...)
- rsa (ssh-rsa ...)
Setting user_sshkeys to [ Unmanaged ] will
instruct divingbell not to manage the user's authorized_keys file.
At least one user must be defined with an SSH key and sudo in order
for the built-in ubuntu account to be disabled.
Purging expired users
Including the purge_expired_users key-value pair is
optional. The default value is false.
This option must be set to true if it is desired to
purge expired accounts and remove their home directories. Otherwise,
removed accounts are expired (so users cannot login) but their home
directories remain intact, in order to maintain UID consistency (in the
event the same accounts gets re-added later, they regain access to their
home directory files without UID mismatching).
Node specific configurations
Although we expect these daemonsets to run indiscriminately on all nodes in the infrastructure, we also expect that different nodes will need to be given a different set of data depending on the node role/function. This chart supports establishing value overrides for nodes with specific label value pairs and for targeting nodes with specific hostnames. The overridden configuration is merged with the normal config data, with the override data taking precedence.
The chart will then generate one daemonset for each host and label override, in addition to a default daemonset for which no overrides are applied. Each daemonset generated will also exclude from its scheduling criteria all other hosts and labels defined in other overrides for the same daemonset, to ensure that there is no overlap of daemonsets (i.e., one and only one daemonset of a given type for each node).
Overrides example with sysctl daemonset:
conf:
sysctl:
net.ipv4.ip_forward: 1
net.ipv6.conf.all.forwarding: 1
fs.file-max: 9999
overrides:
divingbell_sysctl:
labels:
- label:
key: compute_type
values:
- "dpdk"
- "sriov"
conf:
sysctl:
net.ipv4.ip_forward: 0
- label:
key: another_label
values:
- "another_value"
conf:
sysctl:
net.ipv6.conf.all.forwarding: 0
hosts:
- name: superhost
conf:
sysctl:
net.ipv4.ip_forward: 0
fs.file-max: 12345
- name: superhost2
conf:
sysctl:
fs.file-max: 23456Caveats:
- For a given node, at most one override operation applies. If a node meets override criteria for both a label and a host, then the host overrides take precedence and are used for that node. The label overrides are not used in this case. This is especially important to note if you are defining new host overrides for a node that is already consuming matching label overrides, as defining a host override would make those label overrides no longer apply.
- In the event of label conflicts, the last applicable label override defined takes precedence. In this example, overrides defined for "another_label" would take precedence and be applied to nodes that contained both of the defined labels.
Dev Environment with Vagrant
The point of Dev env to prepare working environment for development.
Vagrantfile allows to run on working copy with modifications e.g. to 020-test script. The approach is to setup Gate test but do not delete the pods and other stuff. You have:
- test run of previous tests and their results
- your changes from working tree are applied smoothly
- your not committed test runs in prepared env
Recorded Demo
A recorded demo of using Divingbell can be found here.