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Chapter 5. Security considerations
5.1. FIPS-140-2
The Federal Information Processing Standard Publication 140-2 (FIPS-140-2) is a standard that defines a set of security requirements for the use of cryptographic modules. Law mandates this standard for the US government agencies and contractors and is also referenced in other international and industry specific standards.
Red Hat OpenShift Data Foundation now uses the FIPS validated cryptographic modules. Red Hat Enterprise Linux OS/CoreOS (RHCOS) delivers these modules.
Currently, the Cryptographic Module Validation Program (CMVP) processes the cryptography modules. You can see the state of these modules at Modules in Process List. For more up-to-date information, see the Red Hat Knowledgebase solution RHEL core crypto components.
Enable the FIPS mode on the OpenShift Container Platform, before you install OpenShift Data Foundation. OpenShift Container Platform must run on the RHCOS nodes, as the feature does not support OpenShift Data Foundation deployment on Red Hat Enterprise Linux 7 (RHEL 7).
For more information, see Installing a cluster in FIPS mode and Support for FIPS cryptography of the Installing guide in OpenShift Container Platform documentation.
5.2. Proxy environment
A proxy environment is a production environment that denies direct access to the internet and provides an available HTTP or HTTPS proxy instead. Red Hat Openshift Container Platform is configured to use a proxy by modifying the proxy object for existing clusters or by configuring the proxy settings in the install-config.yaml file for new clusters.
Red Hat supports deployment of OpenShift Data Foundation in proxy environments when OpenShift Container Platform has been configured according to configuring the cluster-wide proxy.
5.3. Data encryption options
Encryption lets you encode your data to make it impossible to read without the required encryption keys. This mechanism protects the confidentiality of your data in the event of a physical security breach that results in a physical media to escape your custody. The per-PV encryption also provides access protection from other namespaces inside the same OpenShift Container Platform cluster. Data is encrypted when it is written to the disk, and decrypted when it is read from the disk. Working with encrypted data might incur a small penalty to performance.
Encryption is only supported for new clusters deployed using Red Hat OpenShift Data Foundation 4.6 or higher. An existing encrypted cluster that is not using an external Key Management System (KMS) cannot be migrated to use an external KMS.
Previously, HashiCorp Vault was the only supported KMS for Cluster-wide and Persistent Volume encryptions. With OpenShift Data Foundation 4.7.0 and 4.7.1, only HashiCorp Vault Key/Value (KV) secret engine API, version 1 is supported. Starting with OpenShift Data Foundation 4.7.2, HashiCorp Vault KV secret engine API, versions 1 and 2 are supported. As of OpenShift Data Foundation 4.12, Thales CipherTrust Manager has been introduced as an additional supported KMS.
- KMS is required for StorageClass encryption, and is optional for cluster-wide encryption.
- To start with, Storage class encryption requires a valid Red Hat OpenShift Data Foundation Advanced subscription. For more information, see the knowledgebase article on OpenShift Data Foundation subscriptions.
Red Hat works with the technology partners to provide this documentation as a service to the customers. However, Red Hat does not provide support for the Hashicorp product. For technical assistance with this product, contact Hashicorp.
5.3.1. Cluster-wide encryption
Red Hat OpenShift Data Foundation supports cluster-wide encryption (encryption-at-rest) for all the disks and Multicloud Object Gateway operations in the storage cluster. OpenShift Data Foundation uses Linux Unified Key System (LUKS) version 2 based encryption with a key size of 512 bits and the aes-xts-plain64
cipher where each device has a different encryption key. The keys are stored using a Kubernetes secret or an external KMS. Both methods are mutually exclusive and you can not migrate between methods.
Encryption is disabled by default for block and file storage. You can enable encryption for the cluster at the time of deployment. The MultiCloud Object Gateway supports encryption by default. See the deployment guides for more information.
Cluster wide encryption is supported in OpenShift Data Foundation 4.6 without Key Management System (KMS). Starting with OpenShift Data Foundation 4.7, it supports with and without HashiCorp Vault KMS. Starting with OpenShift Data Foundation 4.12, it supports with and without both HashiCorp Vault KMS and Thales CipherTrust Manager KMS.
Security common practices require periodic encryption key rotation. Red Hat OpenShift Data Foundation automatically rotates encryption keys stored in kubernetes secret (non-KMS) weekly.
Requires a valid Red Hat OpenShift Data Foundation Advanced subscription. To know how subscriptions for OpenShift Data Foundation work, see knowledgebase article on OpenShift Data Foundation subscriptions.
Cluster wide encryption with HashiCorp Vault KMS provides two authentication methods:
- Token: This method allows authentication using vault tokens. A kubernetes secret containing the vault token is created in the openshift-storage namespace and is used for authentication. If this authentication method is selected then the administrator has to provide the vault token that provides access to the backend path in Vault, where the encryption keys are stored.
Kubernetes: This method allows authentication with vault using serviceaccounts. If this authentication method is selected then the administrator has to provide the name of the role configured in Vault that provides access to the backend path, where the encryption keys are stored. The value of this role is then added to the
ocs-kms-connection-details
config map. This method is available from OpenShift Data Foundation 4.10.Currently, HashiCorp Vault is the only supported KMS. With OpenShift Data Foundation 4.7.0 and 4.7.1, only HashiCorp Vault KV secret engine, API version 1 is supported. Starting with OpenShift Data Foundation 4.7.2, HashiCorp Vault KV secret engine API, versions 1 and 2 are supported.
OpenShift Data Foundation on IBM Cloud platform supports Hyper Protect Crypto Services (HPCS) Key Management Services (KMS) as the encryption solution in addition to HashiCorp Vault KMS.
Red Hat works with the technology partners to provide this documentation as a service to the customers. However, Red Hat does not provide support for the Hashicorp product. For technical assistance with this product, contact Hashicorp.
5.3.2. Storage class encryption
You can encrypt persistent volumes (block only) with storage class encryption using an external Key Management System (KMS) to store device encryption keys. Persistent volume encryption is only available for RADOS Block Device (RBD) persistent volumes. See how to create a storage class with persistent volume encryption.
Storage class encryption is supported in OpenShift Data Foundation 4.7 or higher with HashiCorp Vault KMS. Storage class encryption is supported in OpenShift Data Foundation 4.12 or higher with both HashiCorp Vault KMS and Thales CipherTrust Manager KMS.
Requires a valid Red Hat OpenShift Data Foundation Advanced subscription. To know how subscriptions for OpenShift Data Foundation work, see knowledgebase article on OpenShift Data Foundation subscriptions.
5.3.3. CipherTrust manager
Red Hat OpenShift Data Foundation version 4.12 introduced Thales CipherTrust Manager as an additional Key Management System (KMS) provider for your deployment. Thales CipherTrust Manager provides centralized key lifecycle management. CipherTrust Manager supports Key Management Interoperability Protocol (KMIP), which enables communication between key management systems.
CipherTrust Manager is enabled during deployment.
5.3.4. Data encryption in-transit via Red Hat Ceph Storage’s messenger version 2 protocol (msgr2)
Starting with OpenShift Data Foundation version 4.14, Red Hat Ceph Storage’s messenger version 2 protocol can be used to encrypt data in-transit. This provides an important security requirement for your infrastructure.
In-transit encryption can be enabled during deployment while the cluster is being created. See the deployment guide for your environment for instructions on enabling data encryption in-transit during cluster creation.
The msgr2 protocol supports two connection modes:
crc
- Provides strong initial authentication when a connection is established with cephx.
- Provides a crc32c integrity check to protect against bit flips.
- Does not provide protection against a malicious man-in-the-middle attack.
- Does not prevent an eavesdropper from seeing all post-authentication traffic.
secure
- Provides strong initial authentication when a connection is established with cephx.
- Provides full encryption of all post-authentication traffic.
- Provides a cryptographic integrity check.
The default mode is crc
.
5.4. Encryption in Transit
You need to enable IPsec so that all the network traffic between the nodes on the OVN-Kubernetes Container Network Interface (CNI) cluster network travels through an encrypted tunnel.
By default, IPsec is disabled. You can enable it either during or after installing the cluster. If you need to enable IPsec after cluster installation, you must first resize your cluster MTU to account for the overhead of the IPsec ESP IP header.
For more information on how to configure the IPsec encryption, see Configuring IPsec encryption of the Networking guide in OpenShift Container Platform documentation.