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d3b542d781
* rfc: add numeric ids to existing RFCs
154 lines
7.5 KiB
Markdown
154 lines
7.5 KiB
Markdown
# RFC 005: External KMS
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Currently, Constellation only supports [Constellation-managed key management](https://docs.edgeless.systems/constellation/2.0/architecture/keys#constellation-managed-key-management).
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The owner provides a master secret to the cluster on initialization.
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The cluster holds this secret during its lifetime and uses it to derive DEKs for disk encryption.
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In addition, Constellation should support [user-managed key management](https://docs.edgeless.systems/constellation/2.0/architecture/keys#user-managed-key-management) with an external KMS.
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Main goals are:
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* The KEK (master secret) never leaves the KMS. Unencrypted DEKs only exist temporarily.
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* Auto recovery of a cluster without manual intervention.
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We need to decide on how to implement the KMIP client and what reference KMIP servers we want to implement against in the first iteration.
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## Details on status quo
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The CLI generates the master secret and passes it to the Bootstrapper on init.
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The CLI also injects it into the Helm charts as a Kubernetes secret for the Constellation KMS service (referred to as CKMS in the following to avoid confusion).
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The Bootstrapper uses the master secret to
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* derive the *measurement salt* and the *clusterID*.
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* derive the DEK and set up the state disk.
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Note that the Bootstrapper performs these operations itself.
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Particularly, it replicates the DEK derivation of the CKMS in ClusterKMS mode.
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The CKMS serves a gRPC API to get DEKs.
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It's designed to support different (cloud) KMS services as backend.
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Currently, only the ClusterKMS backend is used, which uses the master secret from the Kubernetes secrets to derive the DEKs.
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The clients of the CKMS are the join-service and the CSI drivers.
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### Recovery
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When a node boots, the disk-mapper will setup the encrypted state disk during initramfs.
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To decrypt an already existing disks, the disk-mapper will ask all available joinservice instances for a decryption key for it's current disk UUID.
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In case there is no join-service instance that can provide the decryption key, manual recovery becomes necessary.
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To enable manual recovery the disk-mapper starts a recovery server.
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The recovery server waits for a `recover` gRPC call.
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During a `recover` call the CLI will attest the measurements of the node.
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After successful attestation the CLI will provide a disk decryption key and measurement secret for the given disk UUID.
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The measurement secret, together with a measurement salt (not secret) is used to derive the clusterID.
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*Changes for eKMS; regarding disk decryption:*
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* Recovery server accepts KMS URI, storage URI and kms/storage IAM secret instead of a masterSecret. During normal operation the KMS service has access to the IAM secrets through a mounted k8s secret. This secret is not available during initramfs.
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* For eKMS backends the two URIs can be used directly to request new DEKs.
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* For the cKMS backend the KMS URI can include an optional parameter that holds the masterSecret: `kms://cluster-kms?masterSecret=<masterSecret>`.
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The above approach allows us to integrate with the existing setup code in `keyservice/setup/setup.go` with only minimal changes (parse masterSecret in case of cluster-kms).
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This code is used to setup CloudKMS objects.
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The `setup.go` code will have to be refactored to live in `internal` so that the disk-mapper pkg can directly communicate with the respective external KMS.
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### Implemented, but yet unused features
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There are CKMS backends for Azure, GCP, and AWS.
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These should be working, but aren't battle-tested.
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The init gRPC API has the following fields:
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```
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bytes master_secret = 2;
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string kms_uri = 3;
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string storage_uri = 4;
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string key_encryption_key_id = 5;
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bool use_existing_kek = 6;
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bytes salt = 10;
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```
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* `master_secret` (and `salt`) are used as described above. The other fields are unused.
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* `kms_uri` and `storage_uri` contain the type and configuration of the (external) KMS and storage to use. The CKMS already has logic to parse them and create corresponding backends.
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* `key_encryption_key_id` and `use_existing_kek` are supposed to control how the external KMS is used.
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## Overview of Hashicorp Vault's KMS integrations
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Multiple features of Vault integrate with KMSs.
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### KMS secrets engine
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A KMS secrets engine uses an external KMS to perform operations like encryption and decryption.
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Vault provides a [KMS engine for GCP](https://developer.hashicorp.com/vault/docs/secrets/gcpkms) only.
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### Auto unseal
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When you start Vault, it's in a sealed state.
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You must provide the seal key to unseal it.
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This is similar to recovering a Constellation cluster.
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Instead of manually providing the key, you can configure Vault to [automatically use a KMS to decrypt its root key](https://developer.hashicorp.com/vault/docs/concepts/seal#auto-unseal).
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You can use Azure, GCP, and AWS KMSs among others, but not KMIP.
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Vault enterprise features [seal wrap](https://developer.hashicorp.com/vault/docs/enterprise/sealwrap).
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This is an "extra layer of protection" that uses a KMS to encrypt single values before storing them in Vault.
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The docs promote this as a means of meeting compliance requirements rather than improving security.
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### KMIP server
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Vault can act as a [KMIP server](https://developer.hashicorp.com/vault/docs/secrets/kmip).
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This means that clients can connect to Vault via both the native API and a KMIP API.
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Vault does *not* provide any KMIP client functionality.
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### Go-KMS-Wrapping
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https://github.com/hashicorp/go-kms-wrapping
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This library wraps various KMS services and provides a common interface to them.
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It's similar to the CKMS implementation.
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We may consider to replace our own implementation with this.
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However, it also doesn't have support for KMIP.
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### Conclusion
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We can't use Vault as a component of Constellation to add KMIP support.
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We also can't use it as a cloud KMS proxy because it only supports GCP.
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We could use Vault as DEK storage and use auto unseal with cloud KMS to replace the master secret.
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However, we would need a separate way for KMIP support.
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We should probably go with adding native support for external KMSs.
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We may use Vault as a reference KMIP server to implement against, but we need to procure Vault Enterprise and the ADP module for it.
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## Other tools and libraries
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### PyKMIP
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[PyKMIP](https://github.com/OpenKMIP/PyKMIP) is a KMIP client library for Python.
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Part of the project is a [KMIP server](https://pykmip.readthedocs.io/en/latest/server.html) for testing.
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We may use it as a reference KMIP server to implement against.
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### kmip-go
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[kmip-go](https://github.com/ThalesGroup/kmip-go) provides [KMIP protocol structures and can encode](https://pkg.go.dev/github.com/gemalto/kmip-go#example-package-Client) and decode them.
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We can use this as a building block of the Constellation KMIP client.
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It also has a [server type](https://pkg.go.dev/github.com/gemalto/kmip-go#Server) that may be useful in unit tests.
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## Tasks
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* Decide whether we want to replace our own implementations with Go-KMS-Wrapping
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* Plan recovery with external KMS
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* The code of the Bootstrapper (and recovery) dealing with the master secret should be centralized and shared with the CKMS implementation
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* Implement the variant that uses an external KMS instead of the master key for these functionalities
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* Expose CKMS configuration to the user
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* Implement KMIP as a backend for the CKMS
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* Use kmip-go for the client logic
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* Use kmip-go's server type for unit tests
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* Use PyKMIP's server for integration tests
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* Use Vault Enterprise+ADP for extended integration and/or e2e tests
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## Issues
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Can we achieve recovery of a cluster without manual intervention with KMIP?
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How to authenticate?
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