Installing Satellite Server in a connected network environment

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1. Preparing your environment for installation

Review the following prerequisites before you install Satellite Server.

For interactive instructions for performing the installation, you can use the Red Hat Satellite Installation Helper on the Red Hat Customer Portal. This application provides you with an interactive way to prepare installation instructions customized for your required Satellite version number and configuration. For more information, see Red Hat Satellite Installation Helper on the Red Hat Customer Portal.

1.1. System requirements

The following requirements apply to the networked base operating system:

x86_64 architecture
The latest version of Red Hat Enterprise Linux 9
4-core 2.0 GHz CPU at a minimum
A minimum of 20 GB RAM is required for Satellite Server to function. In addition, a minimum of 4 GB RAM of swap space is also recommended. Satellite running with less RAM than the minimum value might not operate correctly.
A unique host name, which can contain lower-case letters, numbers, dots (.) and hyphens (-)
A current Red Hat Satellite subscription
Administrative user (root) access
Full forward and reverse DNS resolution using a fully-qualified domain name

Satellite only supports UTF-8 encoding. If your territory is USA and your language is English, set en_US.utf-8 as the system-wide locale settings. For more information about configuring system locale in Red Hat Enterprise Linux, see Configuring the system locale in Red Hat Enterprise Linux 9 Configuring basic system settings.

Your Satellite must have the Red Hat Satellite Infrastructure Subscription manifest in your Customer Portal. Satellite must have satellite-capsule-6.x repository enabled and synced. To create, manage, and export a Red Hat Subscription Manifest in the Customer Portal, see Creating and managing manifests for a connected Satellite Server in Subscription Central.

Satellite Server and Capsule Server do not support shortnames in the hostnames. When using custom certificates, the Common Name (CN) of the custom certificate must be a fully qualified domain name (FQDN) instead of a shortname. This does not apply to the clients of a Satellite.

Before you install Satellite Server, ensure that your environment meets the requirements for installation.

Satellite Server must be installed on a freshly provisioned system that serves no other function except to run Satellite Server. The freshly provisioned system must not have the following users provided by external identity providers to avoid conflicts with the local users that Satellite Server creates:

apache
foreman
foreman-proxy
postgres
pulp
puppet
redis
tomcat

Certified hypervisors

Satellite Server is fully supported on both physical systems and virtual machines that run on hypervisors that are supported to run Red Hat Enterprise Linux. For more information about certified hypervisors, see Certified Guest Operating Systems in Red Hat OpenStack Services on OpenShift, Red Hat Virtualization, Red Hat OpenShift Virtualization and Red Hat Enterprise Linux with KVM.

SELinux mode

SELinux must be enabled, either in enforcing or permissive mode. Installation with disabled SELinux is not supported.

Synchronized system clock

The system clock on the base operating system where you are installing your Satellite Server must be synchronized across the network. If the system clock is not synchronized, SSL certificate verification might fail. For example, you can use the Chrony suite for timekeeping. For more information, see Configuring time synchronization in Red Hat Enterprise Linux 9 Configuring basic system settings

FIPS mode

You can install Satellite on a Red Hat Enterprise Linux system that is operating in FIPS mode. You cannot enable FIPS mode after the installation of Satellite. For more information, see Switching RHEL to FIPS mode in Red Hat Enterprise Linux 9 Security hardening.

Note

Satellite supports DEFAULT and FIPS crypto-policies. The FUTURE crypto-policy is not supported for Satellite and Capsule installations. The FUTURE policy is a stricter forward-looking security level intended for testing a possible future policy. For more information, see Using system-wide cryptographic policies in Red Hat Enterprise Linux 9 Security hardening.

Inter-Satellite Synchronization (ISS)

In a scenario with air-gapped Satellite Servers, all your Satellite Servers must be on the same Satellite version for ISS Export Sync to work. ISS Network Sync works across all Satellite versions that support it. For more information, see Synchronizing Content Between Satellite Servers in Managing content.

1.2. Storage requirements

The following table details storage requirements for specific directories. These values are based on expected use case scenarios and can vary according to individual environments.

The runtime size was measured with Red Hat Enterprise Linux 7, 8, and 9 repositories synchronized.

Table 1. Storage requirements for a Satellite Server installation
Directory	Installation Size	Runtime Size
/var/log	10 MB	10 GB
/var/lib/pgsql	100 MB	20 GB
/usr	10 GB	Not Applicable
/opt/puppetlabs	500 MB	Not Applicable
/var/lib/pulp	1 MB	300 GB

For external database servers: /var/lib/pgsql with installation size of 100 MB and runtime size of 20 GB.

For detailed information on partitioning and size, see Disk partitions in Red Hat Enterprise Linux 9 Managing storage devices.

1.3. Storage guidelines

Consider the following guidelines when installing Satellite Server to increase efficiency.

If you mount the /tmp directory as a separate file system, you must use the exec mount option in the /etc/fstab file. If /tmp is already mounted with the noexec option, you must change the option to exec and re-mount the file system. This is a requirement for the puppetserver service to work.
Because most Satellite Server data is stored in the /var directory, mounting /var on LVM storage can help the system to scale.
Use high-bandwidth, low-latency storage for the /var/lib/pulp/ and PostgreSQL /var/lib/pgsql directories. As Red Hat Satellite has many operations that are I/O intensive, using high latency, low-bandwidth storage causes performance degradation.

You can use the storage-benchmark script to get this data. For more information on using the storage-benchmark script, see Impact of Disk Speed on Satellite Operations.

File system guidelines

Do not use the GFS2 file system as the input-output latency is too high.

Log file storage

Log files are written to /var/log/messages/, /var/log/httpd/, and /var/lib/foreman-proxy/openscap/content/. You can manage the size of these files using logrotate. For more information, see How to use logrotate utility to rotate log files.

The exact amount of storage you require for log messages depends on your installation and setup.

SELinux considerations for NFS mount

When the /var/lib/pulp directory is mounted using an NFS share, SELinux blocks the synchronization process. To avoid this, specify the SELinux context of the /var/lib/pulp directory in the file system table by adding the following lines to /etc/fstab:

nfs.example.com:/nfsshare  /var/lib/pulp  nfs  context="system_u:object_r:var_lib_t:s0"  1 2

If NFS share is already mounted, remount it using the above configuration and enter the following command:

# restorecon -R /var/lib/pulp

Duplicated packages

Packages that are duplicated in different repositories are only stored once on the disk. Additional repositories containing duplicate packages require less additional storage. The bulk of storage resides in the /var/lib/pulp/ directory. These end points are not manually configurable. Ensure that storage is available on the /var file system to prevent storage problems.

Symbolic links

You cannot use symbolic links for /var/lib/pulp/.

Synchronized RHEL ISO

If you plan to synchronize RHEL content ISOs to Satellite, note that all minor versions of Red Hat Enterprise Linux also synchronize. You must plan to have adequate storage on your Satellite to manage this.

1.4. Supported operating systems

You can install the operating system from a disc, local ISO image, Kickstart, or any other method that Red Hat supports. Red Hat Satellite Server is supported on the latest version of Red Hat Enterprise Linux 9 that is available at the time when Satellite Server is installed. Previous versions of Red Hat Enterprise Linux including EUS or z-stream are not supported.

The following operating systems are supported by the installer, have packages, and are tested for deploying Satellite:

Table 2. Operating systems supported by satellite-installer
Operating System	Architecture	Notes
Red Hat Enterprise Linux 9	x86_64 only

Red Hat advises against using an existing system because the Satellite installer will affect the configuration of several components. Red Hat Satellite Server requires a Red Hat Enterprise Linux installation with the @Base package group with no other package-set modifications, and without third-party configurations or software not directly necessary for the direct operation of the server. This restriction includes hardening and other non-Red Hat security software. If you require such software in your infrastructure, install and verify a complete working Satellite Server first, then create a backup of the system before adding any non-Red Hat software.

Red Hat does not support using the system for anything other than running Satellite Server.

1.5. Supported browsers

Satellite supports recent versions of Firefox and Google Chrome browsers.

The Satellite web UI and command-line interface support English, French, Japanese, Korean, and Simplified Chinese.

1.6. Port and firewall requirements

For the components of Satellite architecture to communicate, ensure that the required network ports are open and free on the base operating system. You must also ensure that the required network ports are open on any network-based firewalls.

Use this information to configure any network-based firewalls. Note that some cloud solutions must be specifically configured to allow communications between machines because they isolate machines similarly to network-based firewalls. If you use an application-based firewall, ensure that the application-based firewall permits all applications that are listed in the tables and known to your firewall. If possible, disable the application checking and allow open port communication based on the protocol.

Integrated Capsule

Satellite Server has an integrated Capsule and any host that is directly connected to Satellite Server is a Client of Satellite in the context of this section. This includes the base operating system on which Capsule Server is running.

Clients of Capsule

Hosts which are clients of Capsules, other than Satellite’s integrated Capsule, do not need access to Satellite Server. For more information on Satellite Topology and an illustration of port connections, see Capsule Networking in Overview, concepts, and deployment considerations.

Required ports can change based on your configuration.

The following tables indicate the destination port and the direction of network traffic:

Table 3. Satellite Server incoming traffic
Destination Port	Protocol	Service	Source	Required For	Description
53	TCP and UDP	DNS	DNS Servers and clients	Name resolution	DNS (optional)
67	UDP	DHCP	Client	Dynamic IP	DHCP (optional)
69	UDP	TFTP	Client	TFTP Server (optional)
443	TCP	HTTPS	Capsule	Red Hat Satellite API	Communication from Capsule
443, 80	TCP	HTTPS, HTTP	Client	Global Registration	Registering hosts to Satellite Port 443 is required for registration initiation, uploading facts, and sending installed packages and traces Port 80 notifies Satellite on the `/unattended/built` endpoint that registration has finished
443	TCP	HTTPS	Red Hat Satellite	Content Mirroring	Management
443	TCP	HTTPS	Red Hat Satellite	Capsule API	Smart Proxy functionality
443, 80	TCP	HTTPS, HTTP	Capsule	Content Retrieval	Content
443, 80	TCP	HTTPS, HTTP	Client	Content Retrieval	Content
1883	TCP	MQTT	Client	Pull based REX (optional)	Content hosts for REX job notification (optional)
5910 – 5930	TCP	HTTPS	Browsers	Compute Resource’s virtual console
8000	TCP	HTTP	Client	Provisioning templates	Template retrieval for client installers, iPXE or UEFI HTTP Boot
8000	TCP	HTTPS	Client	PXE Boot	Installation
8140	TCP	HTTPS	Client	Puppet agent	Client updates (optional)
9090	TCP	HTTPS	Red Hat Satellite	Capsule API	Smart Proxy functionality
9090	TCP	HTTPS	Client	OpenSCAP	Configure Client (if the OpenSCAP plugin is installed)
9090	TCP	HTTPS	Discovered Node	Discovery	Host discovery and provisioning (if the discovery plugin is installed)
9090	TCP	HTTPS	Client	Pull based REX (optional)	Content hosts for REX job notification (optional)

Any host that is directly connected to Satellite Server is a client in this context because it is a client of the integrated Capsule. This includes the base operating system on which a Capsule Server is running.

A DHCP Capsule performs ICMP ping or TCP echo connection attempts to hosts in subnets with DHCP IPAM set to find out if an IP address considered for use is free. This behavior can be turned off using satellite-installer --foreman-proxy-dhcp-ping-free-ip=false.

Note	Some outgoing traffic returns to Satellite to enable internal communication and security operations.

Table 4. Satellite Server outgoing traffic
Destination Port	Protocol	Service	Destination	Required For	Description
	ICMP	ping	Client	DHCP	Free IP checking (optional)
7	TCP	echo	Client	DHCP	Free IP checking (optional)
22	TCP	SSH	Target host	Remote execution	Run jobs
22, 16514	TCP	SSH SSH/TLS	Compute Resource	Satellite originated communications, for compute resources in libvirt
53	TCP and UDP	DNS	DNS Servers on the Internet	DNS Server	Resolve DNS records (optional)
53	TCP and UDP	DNS	DNS Server	Capsule DNS	Validation of DNS conflicts (optional)
53	TCP and UDP	DNS	DNS Server	Orchestration	Validation of DNS conflicts
68	UDP	DHCP	Client	Dynamic IP	DHCP (optional)
80	TCP	HTTP	Remote repository	Content Sync	Remote repositories
389, 636	TCP	LDAP, LDAPS	External LDAP Server	LDAP	LDAP authentication, necessary only if external authentication is enabled. The port can be customized when `LDAPAuthSource` is defined
443	TCP	HTTPS	Satellite	Capsule	Capsule Configuration management Template retrieval OpenSCAP Remote Execution result upload
443	TCP	HTTPS	Amazon EC2, Azure, Google GCE	Compute resources	Virtual machine interactions (query/create/destroy) (optional)
443	TCP	HTTPS	console.redhat.com	Red Hat Cloud plugin API calls
443	TCP	HTTPS	cdn.redhat.com	Content Sync	Red Hat CDN
443	TCP	HTTPS	cert.console.redhat.com	Red Hat Insights	When using Insights, required for Inventory upload and Cloud Connector connection
443	TCP	HTTPS	api.access.redhat.com	SOS report	Assisting support cases filed through the Red Hat Customer Portal (optional)
443	TCP	HTTPS	cert-api.access.redhat.com	Telemetry data upload and report
443	TCP	HTTPS	connect.cloud.redhat.com:443	RHCD communication with the MQTT message broker
443	TCP	HTTPS	Capsule	Content mirroring	Initiation
443	TCP	HTTPS	Infoblox DHCP Server	DHCP management	When using Infoblox for DHCP, management of the DHCP leases (optional)
623			Client	Power management	BMC On/Off/Cycle/Status
5000	TCP	HTTPS	OpenStack Compute Resource	Compute resources	Virtual machine interactions (query/create/destroy) (optional)
5900 – 5930	TCP	SSL/TLS	Hypervisor	noVNC console	Launch noVNC console
7911	TCP	DHCP, OMAPI	DHCP Server	DHCP	The DHCP target is configured using `--foreman-proxy-dhcp-server` and defaults to localhost ISC and `remote_isc` use a configurable port that defaults to 7911 and uses OMAPI
8443	TCP	HTTPS	Client	Discovery	Capsule sends reboot command to the discovered host (optional)
9090	TCP	HTTPS	Capsule	Capsule API	Management of Capsules

1.7. AWS Requirements

Installing and running Satellite Server and Capsule Servers on Amazon Web Services (AWS) has additional requirements to your environment.

Amazon Web Service requirements

Use Storage requirements in Installing Satellite Server in a connected network environment to understand and assign the correct storage to your AWS EBS volumes. See also an AWS storage optimized instance for further guidance.
Create EBS volumes for directories expected to contain larger amounts of data like /var/lib/pulp and ensure they are correctly mounted on start-up and before continuing the installation.
Optional: Store other data on a separate EBS volume.
If you want Satellite Server and Capsule Server to communicate using external DNS hostnames, open the required ports for communication in the AWS Security Group that is associated with the instance.

AWS permission requirements

Create and access Red Hat Enterprise Linux images in AWS
Edit network access in AWS Security
Create EC2 instances and EBS volumes
Launch EC2 instances
Import and export of virtual machines in AWS
Usage of AWS Direct Connect

Satellite requirements

Ensure that your Amazon EC2 instance meets or exceeds requirements for Satellite:

For Satellite Server, see Preparing your environment for installation in Installing Satellite Server in a connected network environment.
For Capsule Servers, see Preparing your environment for installation in Installing Capsule Server.

Red Hat Cloud prerequisites

Register with Red Hat Cloud Access.
Migrate any Red Hat subscriptions that you want to use.
Create an AWS instance and deploy a Red Hat Enterprise Linux virtual machine to the instance. For more information about deploying Red Hat Enterprise Linux in AWS, see How to Locate Red Hat Cloud Access Gold Images on AWS EC2.
Ensure that your subscriptions are eligible for transfer to Red Hat Cloud. For more information, see Red Hat Cloud Access Program Details.

Additional resources

For more information about Amazon Web Services and terminology, see Amazon Elastic Compute Cloud Documentation.
For more information about Amazon Web Services Direct Connect, see What is AWS Direct Connect?.

1.8. Enabling connections from a client to Satellite Server

Capsules and Content Hosts that are clients of a Satellite Server’s internal Capsule require access through Satellite’s host-based firewall and any network-based firewalls.

Use this procedure to configure the host-based firewall on the system that Satellite is installed on, to enable incoming connections from Clients, and to make the configuration persistent across system reboots. For more information on the ports used, see Port and firewall requirements in Installing Satellite Server in a connected network environment.

Procedure

Open the ports for clients on Satellite Server:

# firewall-cmd \
--add-port="8000/tcp" \
--add-port="9090/tcp"

Allow access to services on Satellite Server:

# firewall-cmd \
--add-service=dns \
--add-service=dhcp \
--add-service=tftp \
--add-service=http \
--add-service=https \
--add-service=puppetmaster

Make the changes persistent:
```
# firewall-cmd --runtime-to-permanent
```

Verification

Enter the following command:
```
# firewall-cmd --list-all
```

For more information, see Using and configuring firewalld in Red Hat Enterprise Linux 9 Configuring firewalls and packet filters.

1.9. Verifying DNS resolution

Verify the full forward and reverse DNS resolution using a fully-qualified domain name to prevent issues while installing Satellite.

Procedure

Ensure that the host name and local host resolve correctly:

# ping -c1 localhost
# ping -c1 `hostname -f` # my_system.domain.com

Successful name resolution results in output similar to the following:

# ping -c1 localhost
PING localhost (127.0.0.1) 56(84) bytes of data.
64 bytes from localhost (127.0.0.1): icmp_seq=1 ttl=64 time=0.043 ms

--- localhost ping statistics ---
1 packets transmitted, 1 received, 0% packet loss, time 0ms
rtt min/avg/max/mdev = 0.043/0.043/0.043/0.000 ms

# ping -c1 `hostname -f`
PING hostname.gateway (XX.XX.XX.XX) 56(84) bytes of data.
64 bytes from hostname.gateway (XX.XX.XX.XX): icmp_seq=1 ttl=64 time=0.019 ms

--- localhost.gateway ping statistics ---
1 packets transmitted, 1 received, 0% packet loss, time 0ms
rtt min/avg/max/mdev = 0.019/0.019/0.019/0.000 ms

To avoid discrepancies with static and transient host names, set all the host names on the system by entering the following command:
```
# hostnamectl set-hostname name
```

For more information, see Changing a hostname using hostnamectl in Red Hat Enterprise Linux 9 Configuring and managing networking.

Warning

Name resolution is critical to the operation of Satellite. If Satellite cannot properly resolve its fully qualified domain name, tasks such as content management, subscription management, and provisioning will fail.

1.10. Tuning Satellite Server with predefined profiles

If your Satellite deployment includes more than 5000 hosts, you can use predefined tuning profiles to improve performance of Satellite.

Note that you cannot use tuning profiles on Capsules.

You can choose one of the profiles depending on the number of hosts your Satellite manages and available hardware resources.

The tuning profiles are available in the /usr/share/foreman-installer/config/foreman.hiera/tuning/sizes directory.

When you run the satellite-installer command with the --tuning option, deployment configuration settings are applied to Satellite in the following order:

The default tuning profile defined in the /usr/share/foreman-installer/config/foreman.hiera/tuning/common.yaml file
The tuning profile that you want to apply to your deployment and is defined in the /usr/share/foreman-installer/config/foreman.hiera/tuning/sizes/ directory
Optional: If you have configured a /etc/foreman-installer/custom-hiera.yaml file, Satellite applies these configuration settings.

Note that the configuration settings that are defined in the /etc/foreman-installer/custom-hiera.yaml file override the configuration settings that are defined in the tuning profiles.

Therefore, before applying a tuning profile, you must compare the configuration settings that are defined in the default tuning profile in /usr/share/foreman-installer/config/foreman.hiera/tuning/common.yaml, the tuning profile that you want to apply and your /etc/foreman-installer/custom-hiera.yaml file, and remove any duplicated configuration from the /etc/foreman-installer/custom-hiera.yaml file.

default: Number of hosts: 0 – 5000

RAM: 20G

Number of CPU cores: 4
medium: Number of hosts: 5001 – 10000

RAM: 32G

Number of CPU cores: 8
large: Number of hosts: 10001 – 20000

RAM: 64G

Number of CPU cores: 16
extra-large: Number of hosts: 20001 – 60000

RAM: 128G

Number of CPU cores: 32
extra-extra-large: Number of hosts: 60000+

RAM: 256G

Number of CPU cores: 48+

Procedure

Optional: If you have configured the custom-hiera.yaml file on Satellite Server, back up the /etc/foreman-installer/custom-hiera.yaml file to custom-hiera.original. You can use the backup file to restore the /etc/foreman-installer/custom-hiera.yaml file to its original state if it becomes corrupted:
```
# cp /etc/foreman-installer/custom-hiera.yaml \
/etc/foreman-installer/custom-hiera.original
```
Optional: If you have configured the custom-hiera.yaml file on Satellite Server, review the definitions of the default tuning profile in /usr/share/foreman-installer/config/foreman.hiera/tuning/common.yaml and the tuning profile that you want to apply in /usr/share/foreman-installer/config/foreman.hiera/tuning/sizes/. Compare the configuration entries against the entries in your /etc/foreman-installer/custom-hiera.yaml file and remove any duplicated configuration settings in your /etc/foreman-installer/custom-hiera.yaml file.
Enter the satellite-installer command with the --tuning option for the profile that you want to apply. For example, to apply the medium tuning profile settings, enter the following command:
```
# satellite-installer --tuning medium
```

1.11. Requirements for installation in an IPv4 network

The following requirements apply to installations in an IPv4 network:

An IPv6 loopback must be configured on the base system. The loopback is typically configured by default. Do not disable it.
Do not disable IPv6 in kernel by adding the ipv6.disable=1 kernel parameter.

For a supported way to disable the IPv6 protocol, see How do I disable the IPv6 protocol on Red Hat Satellite and/or Red Hat Capsule server? in Red Hat Knowledgebase.

2. Preparing your environment for Satellite installation in an IPv6 network

You can install and use Satellite in an IPv6 network. Before installing Satellite in an IPv6 network, view the limitations and ensure that you meet the requirements.

To provision hosts in an IPv6 network, after installing Satellite, you must also configure Satellite for the UEFI HTTP boot provisioning. For more information, see Configuring Satellite for UEFI HTTP boot provisioning in an IPv6 network.

2.1. Limitations of Satellite installation in an IPv6 network

Satellite installation in an IPv6 network has the following limitations:

You can install Satellite and Capsules in IPv6-only systems, dual-stack installation is not supported.
Although Satellite provisioning templates include IPv6 support for PXE and HTTP (iPXE) provisioning, the only tested and certified provisioning workflow is the UEFI HTTP Boot provisioning. This limitation only relates to users who plan to use Satellite to provision hosts.
Satellite does not support configuring an HTTP proxy using a direct IPv6 address. Instead, configure the HTTP proxy with a FQDN that resolves to the IPv6 address. Using an IPv6 address as the HTTP proxy URL causes it to fail.

2.2. Requirements for Satellite installation in an IPv6 network

Before installing Satellite in an IPv6 network, ensure that you meet the following requirements:

You must deploy an external DHCPv6 server and configure it manually to communicate with the network boot process and to manage IP address assignment because Satellite cannot integrate with a DHCPv6 server and manage its configuration. For more information about DHCPv6 server configuration, see Options in unmanaged DHCPv6 in Provisioning hosts.
You must deploy an external HTTP proxy server that supports both IPv4 and IPv6. This is required because Red Hat Content Delivery Network distributes content only over IPv4 networks, therefore you must use this proxy to pull content into the Satellite on your IPv6 network.
You must configure Satellite to use this dual stack (supporting both IPv4 and IPv6) HTTP proxy server as the default proxy. For more information, see Adding a Default HTTP Proxy to Satellite.

3. Installing Satellite Server

When you install Satellite Server from a connected network, you can obtain packages and receive updates directly from the Red Hat Content Delivery Network.

Note	You cannot register Satellite Server to itself.

Use the following procedures to install Satellite Server, perform the initial configuration, and import subscription manifests. For more information on subscription manifests, see Managing Red Hat Subscriptions in Managing content.

Note that the Satellite installation script is based on Puppet, which means that if you run the installation script more than once, it might overwrite any manual configuration changes. ⁠ To avoid this and determine which future changes apply, use the --noop argument when you run the installation script. This argument ensures that no actual changes are made. Potential changes are written to /var/log/foreman-installer/satellite.log.

Files are always backed up and so you can revert any unwanted changes. For example, in the foreman-installer logs, you can see an entry similar to the following about Filebucket:

/Stage[main]/Dhcp/File[/etc/dhcp/dhcpd.conf]: Filebucketed /etc/dhcp/dhcpd.conf to puppet with sum 622d9820b8e764ab124367c68f5fa3a1

You can restore the previous file as follows:

# puppet filebucket -l \
restore /etc/dhcp/dhcpd.conf 622d9820b8e764ab124367c68f5fa3a1

3.1. Configuring the HTTP proxy to connect to Red Hat CDN

Prerequisites

Your network gateway and the HTTP proxy must allow access to the following hosts:

Host name	Port	Protocol
subscription.rhsm.redhat.com	443	HTTPS
cdn.redhat.com	443	HTTPS
cert.console.redhat.com (if using Red Hat Insights)	443	HTTPS
api.access.redhat.com (if using Red Hat Insights)	443	HTTPS
cert-api.access.redhat.com (if using Red Hat Insights)	443	HTTPS
console.redhat.com (if using Red Hat Insights)	443	HTTPS
connect.cloud.redhat.com (if using Red Hat Insights)	443	HTTPS

Host name

Port

Protocol

subscription.rhsm.redhat.com

443

HTTPS

cdn.redhat.com

443

HTTPS

cert.console.redhat.com (if using Red Hat Insights)

443

HTTPS

api.access.redhat.com (if using Red Hat Insights)

443

HTTPS

cert-api.access.redhat.com (if using Red Hat Insights)

443

HTTPS

console.redhat.com (if using Red Hat Insights)

443

HTTPS

connect.cloud.redhat.com (if using Red Hat Insights)

443

HTTPS

Satellite Server uses SSL to communicate with the Red Hat CDN securely. An SSL interception proxy interferes with this communication. These hosts must be allowlisted on your HTTP proxy.

For a list of IP addresses used by the Red Hat CDN (cdn.redhat.com), see the Knowledgebase article Public CIDR Lists for Red Hat on the Red Hat Customer Portal.

To configure the Subscription Manager with the HTTP proxy, follow the procedure below.

Procedure

On Satellite Server, complete the following details in the /etc/rhsm/rhsm.conf file:

# an http proxy server to use (enter server FQDN)
proxy_hostname = http-proxy.example.com

# port for http proxy server
proxy_port = 8080

# user name for authenticating to an http proxy, if needed
proxy_user =

# password for basic http proxy auth, if needed
proxy_password =

3.2. Registering to Red Hat Subscription Management

Registering the host to Red Hat Subscription Management enables the host to subscribe to and consume content for any subscriptions available to the user. This includes content such as Red Hat Enterprise Linux and Red Hat Satellite.

Procedure

Register your system with the Red Hat Content Delivery Network, entering your Customer Portal user name and password when prompted:
```
# subscription-manager register
```
The command displays output similar to the following:
```
# subscription-manager register
Username: user_name
Password:
The system has been registered with ID: 541084ff2-44cab-4eb1-9fa1-7683431bcf9a
```

3.3. Configuring repositories

Procedure

Disable all repositories:

# subscription-manager repos --disable "*"

Enable the following repositories:

# subscription-manager repos \
--enable=rhel-9-for-x86_64-baseos-rpms \
--enable=rhel-9-for-x86_64-appstream-rpms \
--enable=satellite-6.17-for-rhel-9-x86_64-rpms \
--enable=satellite-maintenance-6.17-for-rhel-9-x86_64-rpms

Verification

Verify that the required repositories are enabled:
```
# dnf repolist enabled
```

3.4. Optional: Using fapolicyd on Satellite Server

By enabling fapolicyd on your Satellite Server, you can provide an additional layer of security by monitoring and controlling access to files and directories. The fapolicyd daemon uses the RPM database as a repository of trusted binaries and scripts.

You can turn on or off the fapolicyd on your Satellite Server or Capsule Server at any point.

3.4.1. Installing fapolicyd on Satellite Server

You can install fapolicyd along with Satellite Server or can be installed on an existing Satellite Server. If you are installing fapolicyd along with the new Satellite Server, the installation process will detect the fapolicyd in your Red Hat Enterprise Linux host and deploy the Satellite Server rules automatically.

Prerequisites

Ensure your host has access to the BaseOS repositories of Red Hat Enterprise Linux.

Procedure

For a new installation, install fapolicyd:
```
# dnf install fapolicyd
```
For an existing installation, install fapolicyd using satellite-maintain packages install:
```
# satellite-maintain packages install fapolicyd
```
Start the fapolicyd service:
```
# systemctl enable --now fapolicyd
```

Verification

Verify that the fapolicyd service is running correctly:
```
# systemctl status fapolicyd
```

New Satellite Server or Capsule Server installations

In case of new Satellite Server or Capsule Server installation, follow the standard installation procedures after installing and enabling fapolicyd on your Red Hat Enterprise Linux host.

Additional resources

For more information on fapolicyd, see Blocking and allowing applications using fapolicyd in Red Hat Enterprise Linux 9 Security hardening.

3.5. Installing Satellite Server packages

Procedure

Update all packages:
```
# dnf upgrade
```
Install Satellite Server packages:
```
# dnf install satellite
```

3.6. Configuring Satellite Server

Install Satellite Server by using the satellite-installer installation script.

This method is performed by running the installation script with one or more command options. The command options override the corresponding default initial configuration options and are recorded in the Satellite answer file. You can run the script as often as needed to configure any necessary options.

3.6.1. Configuring Satellite installation

This initial configuration procedure creates an organization, location, user name, and password. After the initial configuration, you can create additional organizations and locations if required. The initial configuration also installs PostgreSQL databases on the same server.

The installation process can take tens of minutes to complete. If you are connecting remotely to the system, use a utility such as tmux that allows suspending and reattaching a communication session so that you can check the installation progress in case you become disconnected from the remote system. If you lose connection to the shell where the installation command is running, see the log at /var/log/foreman-installer/satellite.log to determine if the process completed successfully.

Considerations

Use the satellite-installer --scenario satellite --help command to display the most commonly used options and any default values.
Use the satellite-installer --scenario satellite --full-help command to display advanced options.
Specify a meaningful value for the option: --foreman-initial-organization. This can be your company name. An internal label that matches the value is also created and cannot be changed afterwards. If you do not specify a value, an organization called Default Organization with the label Default_Organization is created. You can rename the organization name but not the label.
By default, all configuration files configured by the installer are managed. When satellite-installer runs, it overwrites any manual changes to the managed files with the intended values. This means that running the installer on a broken system should restore it to working order, regardless of changes made. For more information on how to apply custom configuration on other services, see Applying Custom Configuration to Satellite.

Procedure

Enter the following command with any additional options that you want to use:

# satellite-installer --scenario satellite \
--foreman-initial-organization "My_Organization" \
--foreman-initial-location "My_Location" \
--foreman-initial-admin-username admin_user_name \
--foreman-initial-admin-password admin_password

The script displays its progress and writes logs to /var/log/foreman-installer/satellite.log.

3.7. Importing a Red Hat subscription manifest into Satellite Server

Use the following procedure to import a Red Hat subscription manifest into Satellite Server.

Note	Simple Content Access (SCA) is set on the organization, not the manifest. Importing a manifest does not change your organization’s Simple Content Access status.

Simple Content Access simplifies the subscription experience for administrators. For more information, see the Subscription Management Administration Guide for Red Hat Enterprise Linux on the Red Hat Customer Portal.

Prerequisites

Ensure you have a Red Hat subscription manifest exported from the Red Hat Hybrid Cloud Console. For more information, see Creating and managing manifests for a connected Satellite Server in Subscription Central.

Procedure

In the Satellite web UI, ensure the context is set to the organization you want to use.
In the Satellite web UI, navigate to Content > Subscriptions and click Manage Manifest.
In the Manage Manifest window, click Choose File.
Navigate to the location that contains the Red Hat subscription manifest file, then click Open.

CLI procedure

Copy the Red Hat subscription manifest file from your local machine to Satellite Server:
```
$ scp ~/manifest_file.zip root@satellite.example.com:~/.
```
Log in to Satellite Server as the root user and import the Red Hat subscription manifest file:
```
$ hammer subscription upload \
--file ~/manifest_file.zip \
--organization "My_Organization"
```

You can now enable repositories and import Red Hat content. For more information, see Importing Content in Managing content.

4. Performing additional configuration on Satellite Server

4.1. Using Red Hat Insights with Satellite Server

You can use Red Hat Insights to diagnose systems and downtime related to security exploits, performance degradation and stability failures. You can use the dashboard to quickly identify key risks to stability, security, and performance. You can sort by category, view details of the impact and resolution, and then determine what systems are affected.

Note that you do not require a Red Hat Insights entitlement in your subscription manifest. For more information about Satellite and Red Hat Insights, see Red Hat Insights on Satellite Red Hat Enterprise Linux (RHEL).

To maintain your Satellite Server, and improve your ability to monitor and diagnose problems you might have with Satellite, install Red Hat Insights on Satellite Server and register Satellite Server with Red Hat Insights.

Scheduling insights-client

Note that you can change the default schedule for running insights-client by configuring insights-client.timer on Satellite. For more information, see Changing the insights-client schedule in the Client Configuration Guide for Red Hat Insights.

Procedure

To install Red Hat Insights on Satellite Server, enter the following command:
```
# satellite-maintain packages install insights-client
```
To register Satellite Server with Red Hat Insights, enter the following command:
```
# satellite-installer --register-with-insights
```

4.2. Disabling Red Hat Insights registration

If you decide that you will not use Red Hat Insights, you can unregister Satellite Server from Insights.

Prerequisites

You have registered Satellite to Red Hat Insights.

Procedure

To unregister Satellite Server from Red Hat Insights, enter the following command:
```
# insights-client --unregister
```

4.3. Importing the Red Hat Satellite Client 6 repository

The Red Hat Satellite Client 6 repository provides client integration tools, such as katello-host-tools or puppet-agent packages, for hosts registered to Satellite. You must enable the repository, synchronize the repository to your Satellite Server, and enable the repository on your hosts.

4.3.1. Enabling the Red Hat Satellite Client 6 repository

Enable the Red Hat Satellite Client 6 repository for every major version of Red Hat Enterprise Linux that you intend to run on your hosts. After enabling a Red Hat repository, Satellite creates a product for this repository automatically.

Prerequisites

Ensure that a subscription manifest has been imported to your organization. For more information, see Importing a Red Hat subscription manifest into Satellite Server.

Procedure

In the Satellite web UI, navigate to Content > Red Hat Repositories.
Ensure that the RPM repository type is selected.
In the search field, type name ~ "Satellite Client" and press Enter. Optionally, enable the Recommended Repositories filter to limit the results.
Click the name of the required repository to expand the repository set.
For the required architecture, click the + icon to enable the repository.

4.3.2. Synchronizing the Red Hat Satellite Client 6 repository

Synchronize the Red Hat Satellite Client 6 repository to import the content to your Satellite Server.

Prerequisites

You have enabled the Red Hat Satellite Client 6 repository.

Procedure

In the Satellite web UI, navigate to Content > Sync Status.
Click the arrow next to the required product to view available repositories.
Select the repositories you want to synchronize.
Click Synchronize Now.

Additional resources

You can create a sync plan to update the content regularly. For more information, see Creating a sync plan in Managing content.

4.4. Configuring pull-based transport for remote execution

By default, remote execution uses push-based SSH as the transport mechanism for the Script provider. If your infrastructure prohibits outgoing connections from Satellite Server to hosts, you can use remote execution with pull-based transport instead, because the host initiates the connection to Satellite Server. The use of pull-based transport is not limited to those infrastructures.

The pull-based transport comprises pull-mqtt mode on Capsules in combination with a pull client running on hosts.

Note	The `pull-mqtt` mode works only with the Script provider. Ansible and other providers will continue to use their default transport settings.

Procedure

Enable the pull-based transport on your Satellite Server:

# satellite-installer --foreman-proxy-plugin-remote-execution-script-mode=pull-mqtt

Configure the firewall to allow the MQTT service on port 1883:
```
# firewall-cmd --add-service=mqtt
```
Make the changes persistent:
```
# firewall-cmd --runtime-to-permanent
```
In pull-mqtt mode, hosts subscribe for job notifications to either your Satellite Server or any Capsule Server through which they are registered. Ensure that Satellite Server sends remote execution jobs to that same Satellite Server or Capsule Server:
1. In the Satellite web UI, navigate to Administer > Settings.
2. On the Content tab, set the value of Prefer registered through Capsule for remote execution to Yes.

Next steps

Configure your hosts for the pull-based transport. For more information, see Transport modes for remote execution in Managing hosts.

4.5. Configuring Satellite for UEFI HTTP boot provisioning in an IPv6 network

Use this procedure to configure Satellite to provision hosts in an IPv6 network with UEFI HTTP Boot provisioning.

Prerequisites

Ensure that your clients can access DHCP and HTTP servers.
Ensure that the UDP ports 67 and 68 are accessible by clients so clients can send DHCP requests and receive DHCP offers.
Ensure that the TCP port 8000 is open for clients to download files and Kickstart templates from Satellite and Capsules.
Ensure that the host provisioning interface subnet has an HTTP Boot Capsule, and Templates Capsule set. For more information, see Adding a Subnet to Satellite Server in Provisioning hosts.
In the Satellite web UI, navigate to Administer > Settings > Provisioning and ensure that the Token duration setting is not set to 0. Satellite cannot identify clients that are booting from the network by a remote IPv6 address because of unmanaged DHCPv6 service, therefore provisioning tokens must be enabled.

Procedure

You must disable DHCP management in the installer or not use it.
For all IPv6 subnets created in Satellite, set the DHCP Capsule to blank.
Optional: If the host and the DHCP server are separated by a router, configure the DHCP relay agent and point to the DHCP server.

4.6. Configuring Satellite Server with an HTTP proxy

Use the following procedures to configure Satellite with an HTTP proxy.

4.6.1. Adding a default HTTP proxy to Satellite

If your network uses an HTTP Proxy, you can configure Satellite Server to use an HTTP proxy for requests to the Red Hat Content Delivery Network (CDN) or another content source. Use the FQDN instead of the IP address where possible to avoid losing connectivity because of network changes.

The following procedure configures a proxy only for downloading content for Satellite. To use the CLI instead of the Satellite web UI, see the CLI procedure.

Procedure

In the Satellite web UI, navigate to Infrastructure > HTTP Proxies.
Click New HTTP Proxy.
In the Name field, enter the name for the HTTP proxy.
In the Url field, enter the URL of the HTTP proxy in the following format: https://http-proxy.example.com:8080.
Optional: If authentication is required, in the Username field, enter the username to authenticate with.
Optional: If authentication is required, in the Password field, enter the password to authenticate with.
To test connection to the proxy, click Test Connection.
Select the Default content HTTP proxy option to set the new HTTP proxy as default for content synchronization.
Click Submit.

CLI procedure

Verify that the http_proxy, https_proxy, and no_proxy variables are not set:
```
# unset http_proxy https_proxy no_proxy
```

Add an HTTP proxy entry to Satellite and set the HTTP proxy as default for content synchronization:

$ hammer http-proxy create \
--name=My_HTTP_Proxy \
--username=My_HTTP_Proxy_User_Name \
--password=My_HTTP_Proxy_Password \
--url http://http-proxy.example.com:8080 \
--content-default-http-proxy true

4.6.2. Configuring SELinux to ensure access to Satellite on custom ports

SELinux ensures access of Red Hat Satellite and Subscription Manager only to specific ports. In the case of the HTTP cache, the TCP ports are 8080, 8118, 8123, and 10001 – 10010. If you use a port that does not have SELinux type http_cache_port_t, complete the following steps.

Procedure

On Satellite, to verify the ports that are permitted by SELinux for the HTTP cache, enter a command as follows:

# semanage port -l | grep http_cache
http_cache_port_t       tcp    8080, 8118, 8123, 10001-10010
[output truncated]

To configure SELinux to permit a port for the HTTP cache, for example 8088, enter a command as follows:
```
# semanage port -a -t http_cache_port_t -p tcp 8088
```

4.6.3. Using an HTTP proxy for all Satellite HTTP requests

If your Satellite Server must remain behind a firewall that blocks HTTP and HTTPS, you can configure a proxy for communication with external systems, including compute resources.

Note that if you are using compute resources for provisioning, and you want to use a different HTTP proxy with the compute resources, the proxy that you set for all Satellite communication takes precedence over the proxies that you set for compute resources.

Procedure

In the Satellite web UI, navigate to Administer > Settings.
In the HTTP(S) proxy row, select the adjacent Value column and enter the proxy URL.
Click the tick icon to save your changes.

CLI procedure

Enter the following command:

$ hammer settings set --name=http_proxy --value=Proxy_URL

4.6.4. Excluding hosts from receiving proxied requests

If you use an HTTP Proxy for all Satellite HTTP or HTTPS requests, you can prevent certain hosts from communicating through the proxy.

Procedure

In the Satellite web UI, navigate to Administer > Settings.
In the HTTP(S) proxy except hosts row, select the adjacent Value column and enter the names of one or more hosts that you want to exclude from proxy requests.
Click the tick icon to save your changes.

CLI procedure

Enter the following command:

$ hammer settings set --name=http_proxy_except_list --value=[hostname1.hostname2...]

4.6.5. Resetting the HTTP proxy

If you want to reset the current HTTP proxy setting, unset the Default HTTP Proxy setting.

Procedure

In the Satellite web UI, navigate to Administer > Settings, and click the Content tab.
Set the Default HTTP Proxy setting to no global default.

CLI procedure

Set the content_default_http_proxy setting to an empty string:

$ hammer settings set --name=content_default_http_proxy --value=""

4.7. Enabling power management on hosts

To perform power management tasks on hosts using the intelligent platform management interface (IPMI) or a similar protocol, you must enable the baseboard management controller (BMC) module on Satellite Server.

Prerequisites

All hosts must have a network interface of BMC type. Satellite Server uses this NIC to pass the appropriate credentials to the host. For more information, see Configuring a Baseboard Management Controller (BMC) Interface in Managing hosts.

Procedure

To enable BMC, enter the following command:

# satellite-installer \
--foreman-proxy-bmc "true" \
--foreman-proxy-bmc-default-provider "freeipmi"

4.8. Configuring Satellite Server for outgoing emails

To send email messages from Satellite Server, you can use either an SMTP server, or the sendmail command.

Prerequisites

Some SMTP servers with anti-spam protection or grey-listing features are known to cause problems. To setup outgoing email with such a service either install and configure a vanilla SMTP service on Satellite Server for relay or use the sendmail command instead.

Procedure

In the Satellite web UI, navigate to Administer > Settings.

Click the Email tab and set the configuration options to match your preferred delivery method. The changes have an immediate effect.

The following example shows the configuration options for using an SMTP server:

Table 5. Using an SMTP server as a delivery method
Name	Example value	Additional information
Delivery method	SMTP
SMTP address	smtp.example.com
SMTP authentication	login
SMTP HELO/EHLO domain	example.com
SMTP password	password	Use the login credentials for the SMTP server.
SMTP port	25
SMTP username	user@example.com	Use the login credentials for the SMTP server.

The following example uses gmail.com as an SMTP server:

Table 6. Using gmail.com as an SMTP server
Name	Example value	Additional information
Delivery method	SMTP
SMTP address	smtp.gmail.com
SMTP authentication	plain
SMTP HELO/EHLO domain	smtp.gmail.com
SMTP enable StartTLS auto	Yes
SMTP password	app password	Use the Google app password. For more information, see Sign in with app passwords in Google Help Center.
SMTP port	587
SMTP username	user@gmail.com	Use the Google account name.

The following example uses the sendmail command as a delivery method:

Table 7. Using sendmail as a delivery method
Name	Example value	Additional information
Delivery method	Sendmail
Sendmail location	/usr/sbin/sendmail	For security reasons, both Sendmail location and Sendmail argument settings are read-only and can be only set in `/etc/foreman/settings.yaml`. Both settings currently cannot be set via `satellite-installer`. For more information see the sendmail 1 man page.
Sendmail arguments	-i

If you decide to send email using an SMTP server which uses TLS authentication, also perform one of the following steps:
- Mark the CA certificate of the SMTP server as trusted. To do so, execute the following commands on Satellite Server:
  # cp mailca.crt /etc/pki/ca-trust/source/anchors/ # update-ca-trust enable # update-ca-trust
  Where mailca.crt is the CA certificate of the SMTP server.
- Alternatively, in the Satellite web UI, set the SMTP enable StartTLS auto option to No.
Click Test email to send a test message to the user’s email address to confirm the configuration is working. If a message fails to send, the Satellite web UI displays an error. See the log at /var/log/foreman/production.log for further details.

Additional resources

For information on configuring email notifications for individual users or user groups, see Configuring Email Notification Preferences in Administering Red Hat Satellite.

4.9. Configuring Satellite to manage the lifecycle of a host registered to a Identity Management realm

As well as providing access to Satellite Server, hosts provisioned with Satellite can also be integrated with Identity Management realms. Red Hat Satellite has a realm feature that automatically manages the lifecycle of any system registered to a realm or domain provider.

Use this section to configure Satellite Server or Capsule Server for Identity Management realm support, then add hosts to the Identity Management realm group.

Prerequisites

Satellite Server that is registered to the Content Delivery Network or your Capsule Server that is registered to Satellite Server.
A deployed realm or domain provider such as Identity Management.

To install and configure Identity Management packages on Satellite Server or Capsule Server:

To use Identity Management for provisioned hosts, complete the following steps to install and configure Identity Management packages on Satellite Server or Capsule Server:

Install the ipa-client package on Satellite Server or Capsule Server:
```
# satellite-maintain packages install ipa-client
```
Configure the server as a Identity Management client:
```
# ipa-client-install
```
Create a realm proxy user, realm-capsule, and the relevant roles in Identity Management:
```
# foreman-prepare-realm admin realm-capsule
```
Note the principal name that returns and your Identity Management server configuration details because you require them for the following procedure.

To configure Satellite Server or Capsule Server for Identity Management realm support:

Complete the following procedure on Satellite and every Capsule that you want to use:

Copy the /root/freeipa.keytab file to any Capsule Server that you want to include in the same principal and realm:
```
# scp /root/freeipa.keytab root@capsule.example.com:/etc/foreman-proxy/freeipa.keytab
```
On your Satellite Server, move the /root/freeipa.keytab file to the /etc/foreman-proxy directory:
```
# mv /root/freeipa.keytab /etc/foreman-proxy
```
On your Satellite Server and Capsule Servers, set ownership to the foreman-proxy user and group:
```
# chown foreman-proxy:foreman-proxy /etc/foreman-proxy/freeipa.keytab
```
Enter the following command on all Capsules that you want to include in the realm. If you use the integrated Capsule on Satellite, enter this command on Satellite Server:
```
# satellite-installer --foreman-proxy-realm true \
--foreman-proxy-realm-keytab /etc/foreman-proxy/freeipa.keytab \
--foreman-proxy-realm-principal realm-capsule@EXAMPLE.COM \
--foreman-proxy-realm-provider freeipa
```
You can also use these options when you first configure the Satellite Server.
Ensure that the most updated versions of the ca-certificates package is installed and trust the Identity Management Certificate Authority:
```
# cp /etc/ipa/ca.crt /etc/pki/ca-trust/source/anchors/ipa.crt
# update-ca-trust enable
# update-ca-trust
```
Optional: If you configure Identity Management on an existing Satellite Server or Capsule Server, complete the following steps to ensure that the configuration changes take effect:
1. Restart the foreman-proxy service:
  # systemctl restart foreman-proxy
2. In the Satellite web UI, navigate to Infrastructure > Capsules.
3. Locate the Capsule you have configured for Identity Management and from the list in the Actions column, select Refresh.

To create a realm for the Identity Management-enabled Capsule

After you configure your Capsule with Identity Management, you must create a realm and add the Identity Management-configured Capsule to the realm.

Procedure

In the Satellite web UI, navigate to Infrastructure > Realms and click Create Realm.
In the Name field, enter a name for the realm.
From the Realm Type list, select the type of realm.
From the Realm Capsule list, select Capsule Server where you have configured Identity Management.
Click the Locations tab and from the Locations list, select the location where you want to add the new realm.
Click the Organizations tab and from the Organizations list, select the organization where you want to add the new realm.
Click Submit.

Updating host groups with realm information

You must update any host groups that you want to use with the new realm information.

In the Satellite web UI, navigate to Configure > Host Groups, select the host group that you want to update, and click the Network tab.
From the Realm list, select the realm you create as part of this procedure, and then click Submit.

Adding hosts to a Identity Management host group

Identity Management supports the ability to set up automatic membership rules based on a system’s attributes. Red Hat Satellite’s realm feature provides administrators with the ability to map the Red Hat Satellite host groups to the Identity Management parameter userclass which allow administrators to configure automembership.

When nested host groups are used, they are sent to the Identity Management server as they are displayed in the Red Hat Satellite User Interface. For example, "Parent/Child/Child".

Satellite Server or Capsule Server sends updates to the Identity Management server, however automembership rules are only applied at initial registration.

To add hosts to a Identity Management host group:

On the Identity Management server, create a host group:

# ipa hostgroup-add hostgroup_name --desc=hostgroup_description

Create an automembership rule:
```
# ipa automember-add --type=hostgroup hostgroup_name automember_rule
```
Where you can use the following options:
- automember-add flags the group as an automember group.
- --type=hostgroup identifies that the target group is a host group, not a user group.
- automember_rule adds the name you want to identify the automember rule by.
Define an automembership condition based on the userclass attribute:
```
# ipa automember-add-condition --key=userclass --type=hostgroup --inclusive-regex=^webserver hostgroup_name
----------------------------------
Added condition(s) to "hostgroup_name"
----------------------------------
Automember Rule: automember_rule
Inclusive Regex: userclass=^webserver
----------------------------
Number of conditions added 1
----------------------------
```
Where you can use the following options:
- automember-add-condition adds regular expression conditions to identify group members.
- --key=userclass specifies the key attribute as userclass.
- --type=hostgroup identifies that the target group is a host group, not a user group.
- --inclusive-regex= ^webserver identifies matching values with a regular expression pattern.
- hostgroup_name – identifies the target host group’s name.

When a system is added to Satellite Server’s hostgroup_name host group, it is added automatically to the Identity Management server’s "hostgroup_name" host group. Identity Management host groups allow for Host-Based Access Controls (HBAC), sudo policies and other Identity Management functions.

4.10. Configuring an alternate CNAME for Satellite

You can configure an alternate CNAME for Satellite. This might be useful if you want to deploy the Satellite web interface on a different domain name than the one that is used by client systems to connect to Satellite. You must plan the alternate CNAME configuration in advance prior to installing Capsules and registering hosts to Satellite to avoid redeploying new certificates to hosts.

4.10.1. Configuring Satellite with an alternate CNAME

Use this procedure to configure Satellite with an alternate CNAME. Note that the procedures for users of a default Satellite certificate and custom certificate differ.

For default Satellite certificate users

If you have installed Satellite with a default Satellite certificate and want to configure Satellite with an alternate CNAME, enter the following command on Satellite to generate a new default Satellite SSL certificate with an additional CNAME.
```
# satellite-installer --certs-cname alternate_fqdn --certs-update-server
```
If you have not installed Satellite, you can add the --certs-cname alternate_fqdn option to the satellite-installer command to install Satellite with an alternate CNAME.

For custom certificate users

If you use Satellite with a custom certificate, when creating a custom certificate, include the alternate CNAME records to the custom certificate. For more information, see Creating a Custom SSL Certificate for Satellite Server.

4.10.2. Configuring hosts to use an alternate Satellite CNAME for content management

If Satellite is configured with an alternate CNAME, you can configure hosts to use the alternate Satellite CNAME for content management. To do this, you must point hosts to the alternate Satellite CNAME prior to registering the hosts to Satellite. You can do this using the bootstrap script or manually.

Configuring hosts with the bootstrap script

On the host, run the bootstrap script with the --server My-Alternate-FQDN.example.com option to register the host to the alternate Satellite CNAME:

# ./bootstrap.py --server My-Alternate-FQDN.example.com

Configuring hosts manually

On the host, edit the /etc/rhsm/rhsm.conf file to update hostname and baseurl settings to point to the alternate host name, for example:

[server]
# Server hostname:
hostname = My-Alternate-FQDN.example.com

content omitted

[rhsm]
# Content base URL:
baseurl=https://My-Alternate-FQDN.example.com/pulp/content/

Now you can register the host with the subscription-manager.

4.11. Configuring Satellite Server with a custom SSL certificate

By default, Red Hat Satellite uses a self-signed SSL certificate to enable encrypted communications between Satellite Server, Capsule Servers, and all hosts. If you cannot use a Satellite self-signed certificate, you can configure Satellite Server to use an SSL certificate signed by an external certificate authority (CA).

When you configure Red Hat Satellite with custom SSL certificates, you must fulfill the following requirements:

You must use the privacy-enhanced mail (PEM) encoding for the SSL certificates.
You must not use the same SSL certificate for both Satellite Server and Capsule Server.
The same CA must sign certificates for Satellite Server and Capsule Server.
An SSL certificate must not also be a CA certificate.
An SSL certificate must include a subject alt name (SAN) entry that matches the common name (CN).
An SSL certificate must be allowed for Key Encipherment using a Key Usage extension.
An SSL certificate must not have a shortname as the CN.
You must not set a passphrase for the private key.

To configure your Satellite Server with a custom certificate, complete the following procedures:

Creating a custom SSL certificate for Satellite Server
Deploying a custom SSL certificate to Satellite Server
Deploying a custom SSL certificate to hosts
If you have Capsule Servers registered to Satellite Server, configure them with custom SSL certificates. For more information, see Configuring Capsule Server with a Custom SSL Certificate in Installing Capsule Server.

4.11.1. Creating a custom SSL certificate for Satellite Server

Use this procedure to create a custom SSL certificate for Satellite Server. If you already have a custom SSL certificate for Satellite Server, skip this procedure.

Procedure

To store all the source certificate files, create a directory that is accessible only to the root user:
```
# mkdir /root/satellite_cert
```
Create a private key with which to sign the certificate signing request (CSR).

Note that the private key must be unencrypted. If you use a password-protected private key, remove the private key password.

If you already have a private key for this Satellite Server, skip this step.
```
# openssl genrsa -out /root/satellite_cert/satellite_cert_key.pem 4096
```

Create the /root/satellite_cert/openssl.cnf configuration file for the CSR and include the following content:

[ req ]
req_extensions = v3_req
distinguished_name = req_distinguished_name
prompt = no

[ req_distinguished_name ]
commonName = satellite.example.com

[ v3_req ]
basicConstraints = CA:FALSE
keyUsage = digitalSignature, keyEncipherment
extendedKeyUsage = serverAuth, clientAuth
subjectAltName = @alt_names

[ alt_names ]
DNS.1 = satellite.example.com

For more information about the [ v3_req ] parameters and their purpose, see RFC 5280: Internet X.509 Public Key Infrastructure Certificate and Certificate Revocation List (CRL) Profile.

Optional: If you want to add Distinguished Name (DN) details to the CSR, add the following information to the [ req_distinguished_name ] section:

[req_distinguished_name]
CN = satellite.example.com
countryName = My_Country_Name (1)
stateOrProvinceName = My_State_Or_Province_Name (2)
localityName = My_Locality_Name (3)
organizationName = My_Organization_Or_Company_Name
organizationalUnitName = My_Organizational_Unit_Name (4)

Two letter code
Full name
Full name (example: New York)
Division responsible for the certificate (example: IT department)

Generate CSR:

# openssl req -new \
-key /root/satellite_cert/satellite_cert_key.pem \ (1)
-config /root/satellite_cert/openssl.cnf \ (2)
-out /root/satellite_cert/satellite_cert_csr.pem (3)

Path to the private key
Path to the configuration file
Path to the CSR to generate

Send the certificate signing request to the certificate authority (CA). The same CA must sign certificates for Satellite Server and Capsule Server.

When you submit the request, specify the lifespan of the certificate. The method for sending the certificate request varies, so consult the CA for the preferred method. In response to the request, you can expect to receive a CA bundle and a signed certificate, in separate files.

4.11.2. Deploying a custom SSL certificate to Satellite Server

Use this procedure to configure your Satellite Server to use a custom SSL certificate signed by a Certificate Authority.

Important

Do not store the SSL certificates or .tar bundles in /tmp or /var/tmp directory. The operating system removes files from these directories periodically. As a result, satellite-installer fails to execute while enabling features or upgrading Satellite Server.

Procedure

Update certificates on your Satellite Server:

# satellite-installer \
--certs-server-cert "/root/satellite_cert/satellite_cert.pem" \ (1)
--certs-server-key "/root/satellite_cert/satellite_cert_key.pem" \ (2)
--certs-server-ca-cert "/root/satellite_cert/ca_cert_bundle.pem" \ (3)
--certs-update-server --certs-update-server-ca

Path to Satellite Server certificate file that is signed by a Certificate Authority.
Path to the private key that was used to sign Satellite Server certificate.
Path to the Certificate Authority bundle.

Verification

On a computer with network access to Satellite Server, navigate to the following URL: https://satellite.example.com.
In your browser, view the certificate details to verify the deployed certificate.

4.11.3. Deploying a custom SSL certificate to hosts

After you configure Satellite to use a custom SSL certificate, you must deploy the certificate to hosts registered to Satellite.

Procedure

Update the SSL certificate on each host:

# dnf install http://satellite.example.com/pub/katello-ca-consumer-latest.noarch.rpm

4.12. Resetting custom SSL certificate to default self-signed certificate on Satellite Server

Procedure

Reset the custom SSL certificate to default self-signed certificate:
```
# satellite-installer --certs-reset
```

Verification

Verify that the following parameters in /etc/foreman-installer/scenarios.d/satellite-answers.yaml have no values:

server_cert:
server_key:
server_cert_req:
server_ca_cert:

Additional resources

Resetting custom SSL certificate to default self-signed certificate on Capsule Server in Installing Capsule Server.
Resetting custom SSL certificate to default self-signed certificate on hosts in Managing hosts.

4.13. Using external databases with Satellite

The Satellite installation process includes installing a PostgreSQL database on the same host as Satellite Server. In certain Satellite deployments, using external databases instead of the default local databases can help with the server load.

4.13.1. Configuring Satellite Server with external database

Running the satellite-installer command, used to install a Satellite Server, also installs PostgreSQL databases on the server. However, you can configure your Satellite Server to use external databases instead. Moving to external databases distributes the workload and can reduce overall Satellite memory usage.

Note	Red Hat does not provide support or tools for external database maintenance. If you deploy Satellite with external databases, you will need to support and maintain the external databases yourself.

Consider using external databases if you plan to use your Satellite deployment for the following scenarios:

Frequent remote execution tasks. This requires a high volume of records in PostgreSQL and generates heavy database workloads.
High disk I/O workloads from frequent repository synchronization or content view publishing. This requires Satellite to create a record in PostgreSQL for each job.
High volume of hosts.
High volume of synchronized content.

4.13.2. PostgreSQL as an external database considerations

Foreman, Katello, and Candlepin use the PostgreSQL database. If you want to use PostgreSQL as an external database, the following information can help you decide if this option is right for your Satellite configuration. Satellite supports PostgreSQL version 13.

Advantages of external PostgreSQL

Increase in free memory and free CPU on Satellite
Flexibility to set shared_buffers on the PostgreSQL database to a high number without the risk of interfering with other services on Satellite
Flexibility to tune the PostgreSQL server’s system without adversely affecting Satellite operations

Disadvantages of external PostgreSQL

Increase in deployment complexity that can make troubleshooting more difficult
The external PostgreSQL server is an additional system to patch and maintain
If either Satellite or the PostgreSQL database server suffers a hardware or storage failure, Satellite is not operational
If there is latency between the Satellite server and database server, performance can suffer

If you suspect that the PostgreSQL database on your Satellite is causing performance problems, use the information in Satellite 6: How to enable postgres query logging to detect slow running queries to determine if you have slow queries. Queries that take longer than one second are typically caused by performance issues with large installations, and moving to an external database might not help. If you have slow queries, contact Red Hat Support.

4.13.3. Installing PostgreSQL

You can install only the same version of PostgreSQL that is installed with the satellite-installer tool during an internal database installation. Satellite supports PostgreSQL version 13.

Prerequisites

The prepared host must meet Satellite Storage requirements.
The prepared host has base operating system repositories enabled.

Procedure

On your new database server, install PostgreSQL:

# dnf install postgresql-server postgresql-contrib

Initialize the PostgreSQL database:
```
# postgresql-setup --initdb
```
Edit the /var/lib/pgsql/data/postgresql.conf file:
```
# vi /var/lib/pgsql/data/postgresql.conf
```
Note that the default configuration of external PostgreSQL needs to be adjusted to work with Satellite. The base recommended external database configuration adjustments are as follows:
- checkpoint_completion_target: 0.9
- max_connections: 500
- shared_buffers: 512MB
- work_mem: 4MB
Remove the # and edit to listen to inbound connections:
```
listen_addresses = '*'
```
Add the following line to the end of the file to use SCRAM for authentication:
```
password_encryption=scram-sha-256
```
Edit the /var/lib/pgsql/data/pg_hba.conf file:
```
# vi /var/lib/pgsql/data/pg_hba.conf
```

Add the following line to the file:

  host  all   all   Satellite_ip/32   scram-sha-256

Start and enable the PostgreSQL service:
```
# systemctl enable --now postgresql
```
Open the postgresql port:
```
# firewall-cmd --add-service=postgresql
```
Make the changes persistent:
```
# firewall-cmd --runtime-to-permanent
```
Switch to the postgres user and start the PostgreSQL client:
```
$ su - postgres -c psql
```

Create three databases and dedicated roles: one for Foreman, one for Candlepin, and one for Pulp:

CREATE USER "foreman" WITH PASSWORD 'Foreman_Password';
CREATE USER "candlepin" WITH PASSWORD 'Candlepin_Password';
CREATE USER "pulp" WITH PASSWORD 'Pulpcore_Password';
CREATE DATABASE foreman OWNER foreman;
CREATE DATABASE candlepin OWNER candlepin;
CREATE DATABASE pulpcore OWNER pulp;

Exit the postgres user:
```
# \q
```

From Satellite Server, test that you can access the database. If the connection succeeds, the commands return 1.

# PGPASSWORD='Foreman_Password' psql -h postgres.example.com -p 5432 -U foreman -d foreman -c "SELECT 1 as ping"
# PGPASSWORD='Candlepin_Password' psql -h postgres.example.com -p 5432 -U candlepin -d candlepin -c "SELECT 1 as ping"
# PGPASSWORD='Pulpcore_Password' psql -h postgres.example.com -p 5432 -U pulp -d pulpcore -c "SELECT 1 as ping"

4.13.4. Configuring Satellite Server to use external databases

Use the satellite-installer command to configure Satellite to connect to an external PostgreSQL database.

Prerequisites

You have installed and configured a PostgreSQL database on a Red Hat Enterprise Linux server.

Procedure

To configure the external databases for Satellite, enter the following command:

# satellite-installer \
--katello-candlepin-manage-db false \
--katello-candlepin-db-host postgres.example.com \
--katello-candlepin-db-name candlepin \
--katello-candlepin-db-user candlepin \
--katello-candlepin-db-password Candlepin_Password \
--foreman-proxy-content-pulpcore-manage-postgresql false \
--foreman-proxy-content-pulpcore-postgresql-host postgres.example.com \
--foreman-proxy-content-pulpcore-postgresql-db-name pulpcore \
--foreman-proxy-content-pulpcore-postgresql-user pulp \
--foreman-proxy-content-pulpcore-postgresql-password Pulpcore_Password \
--foreman-db-manage false \
--foreman-db-host postgres.example.com \
--foreman-db-database foreman \
--foreman-db-username foreman \
--foreman-db-password Foreman_Password

To enable the Secure Sockets Layer (SSL) protocol for these external databases, add the following options:

--foreman-db-root-cert <path_to_CA>
--foreman-db-sslmode verify-full
--foreman-proxy-content-pulpcore-postgresql-ssl true
--foreman-proxy-content-pulpcore-postgresql-ssl-root-ca <path_to_CA>
--katello-candlepin-db-ssl true
--katello-candlepin-db-ssl-ca <path_to_CA>
--katello-candlepin-db-ssl-verify true

Appendix A: Restoring manual changes overwritten by a Puppet run

If your manual configuration has been overwritten by a Puppet run, you can restore the files to the previous state.

For example, when you install and configure Satellite for the first time by using satellite-installer, you can use the --foreman-proxy-dns-managed=false and --foreman-proxy-dhcp-managed=false options to specify that the DNS and DHCP configuration files are not to be managed by Puppet. If you do not use these options during the initial satellite-installer run, rerunning satellite-installer overwrites all manual changes. The following example shows you how to restore a DHCP configuration file overwritten by a Puppet run.

Procedure

Copy the file you intend to restore. This allows you to compare the files to check for any mandatory changes required by the upgrade. This is not common for DNS or DHCP services.
```
# cp /etc/dhcp/dhcpd.conf /etc/dhcp/dhcpd.backup
```

Check the log files to note down the md5sum of the overwritten file. For example:

# journalctl -xe
...
/Stage[main]/Dhcp/File[/etc/dhcp/dhcpd.conf]: Filebucketed /etc/dhcp/dhcpd.conf to puppet with sum 622d9820b8e764ab124367c68f5fa3a1
...

Restore the overwritten file:

# puppet filebucket restore --local --bucket \
/var/lib/puppet/clientbucket /etc/dhcp/dhcpd.conf \ 622d9820b8e764ab124367c68f5fa3a1

Compare the backup file and the restored file, and edit the restored file to include any mandatory changes required by the upgrade.