diff --git a/docs/kms/README.md b/docs/kms/README.md index fcce0f86a..eda0fe454 100644 --- a/docs/kms/README.md +++ b/docs/kms/README.md @@ -1,56 +1,139 @@ -# KMS Quickstart Guide [![Slack](https://slack.min.io/slack?type=svg)](https://slack.min.io) +# KMS Guide [![Slack](https://slack.min.io/slack?type=svg)](https://slack.min.io) MinIO uses a key-management-system (KMS) to support SSE-S3. If a client requests SSE-S3, or auto-encryption is enabled, the MinIO server encrypts each object with an unique object key which is protected by a master key -managed by the KMS. Usually all object keys are protected by a single master key. +managed by the KMS. -MinIO supports two different KMS concepts: - - External KMS: - MinIO can be configured to use an external KMS i.e. [Hashicorp Vault](https://www.vaultproject.io/). - An external KMS decouples MinIO as storage system from key-management. An external KMS can - be managed by a dedicated security team and allows you to grant/deny access to (certain) objects - by enabling or disabling the corresponding master keys on demand. +> MinIO still provides native Hashicorp Vault support. However, this is feature is **deprecated** and may be +> removed in the future. Therefore, we strongly recommend to use the architecture and KMS Guide below. +> If you have to maintain a legacy MinIO-Vault deployment you can find the legacy documentation [here](./vault-legacy.md). -- Direct KMS master keys: - MinIO can also be configured to directly use a master key specified by the environment variable `MINIO_KMS_MASTER_KEY` or with a docker secret key. - Direct master keys are useful if the storage backend is not on the same machine as the MinIO server, e.g., - if network drives or MinIO gateway is used and an external KMS would cause too much management overhead. +## Architecture and Concepts - Note: KMS master keys are mainly for testing purposes. It's not recommended to use them for production deployments. - Further if the MinIO server machine is ever compromised, then the master key must also be treated as compromised. +The KMS decouples MinIO as an application-facing storage system from the secure key storage and +may be managed by a dedicated security team. In general, the MinIO-KMS infrastructure looks like this: +``` + +-------+ +-----+ + | MinIO +-------+ KMS | + +-------+ +-----+ +``` + +If you scale your storage infrastructure to multiple MinIO clusters your architecture should look like this: +``` + +-------+ +-------+ + | MinIO +----+ +----+ MinIO | + +-------+ | +-----+ | +-------+ + +---+ KMS +---+ + +-------+ | +-----+ | +-------+ + | MinIO +----+ +----+ MinIO | + +-------+ +-------+ +``` + +MinIO supports commonly-used KMS implementations, like [AWS-KMS](https://aws.amazon.com/kms/) or +[Hashicorp Vault](https://www.vaultproject.io/) via our [KES project](https://github.com/minio/kes/wiki). +KES makes it possible to scale your KMS horizontally with your storage infrastructure (MinIO clusters). +Therefore, it wraps around the KMS implementation like this: +``` + +-------+ +-------+ + | MinIO | | MinIO | + +---+---+ +---+---+ + | | + +----+-------------------------+----+---- KMS + | | | | + | +--+--+ +--+--+ | + | | KES +--+ +--+ KES | | + | +-----+ | +-------+ | +-----+ | + | +--+ Vault +--+ | + | +-----+ | +-------+ | +-----+ | + | | KES +--+ +--+ KES | | + | +--+--+ +--+--+ | + | | | | + +----+-------------------------+----+---- KMS + | | + +---+---+ +---+---+ + | MinIO | | MinIO | + +-------+ +-------+ +``` +Observe that all MinIO clusters only have a connection to "their own" KES instance and no direct access to Vault (as one possible KMS implementation). +Each KES instance will handle all encrypton/decryption requests made by "its" MinIO cluster such that the central KMS implementation does not have to handle +a lot of traffic. Instead, each KES instance will use the central KMS implementation as secure key store and fetches the required master keys from it. -**Important:** -If multiple MinIO servers are configured as [gateways](https://github.com/minio/minio/blob/master/docs/gateway/README.md) pointing to the *same* backend - for example the same NAS storage - then the KMS configuration **must** be the same for all gateways. Otherwise one gateway may not be able to decrypt objects created by another gateway. It is the operator responsibility to ensure consistency. +## Get Started Guide -## Get started +In the subsequent sections this guide shows how to setup a MinIO-KMS deployment with Hashicorp Vault as KMS implementation. +Therefore, it shows how to setup and configure: + - A Vault server as central key store. + - A KES server instance as middleware between MinIO and Vault. + - The MinIO instance itself. -### 1. Prerequisites -Install MinIO - [MinIO Quickstart Guide](https://docs.min.io/docs/minio-quickstart-guide). +> Please note that this guide uses self-signed certificates for simplicity. In a production deployment you should use +> X.509 certificates issued by a "public" (e.g. Let's Encrypt) or your organization-internal CA. -### 2. Setup a KMS +This guide shows how to set up three different servers on the same machine: + - The Vault server as `https://127.0.0.1:8200` + - The KES server as `https://127.0.0.1:7373` + - The MinIO server as `https://127.0.0.1:9000` -Either use Hashicorp Vault as external KMS or specify a master key directly depending on your use case. +### 1 Prerequisites -#### 2.1 Setup Hashicorp Vault +Install MinIO, KES and Vault. For MinIO take a look at the [MinIO quickstart guide](https://docs.min.io/docs/minio-quickstart-guide). +Then download the [latest KES binary](https://github.com/minio/kes/releases/latest/) and the [latest Vault binary](https://github.com/hashicorp/vault/releases/latest/) +for your OS and platform. -Here is a sample quick start for configuring vault with a transit backend and Approle with correct policy +### 2 Generate TLS certificates -MinIO requires the following Vault setup: -- The [transit backend](https://www.vaultproject.io/api/secret/transit/index.html) configured with a named encryption key-ring -- [AppRole](https://www.vaultproject.io/docs/auth/approle.html) based authentication with read/update policy for transit backend. In particular, read and update policy are required for the [Generate Data Key](https://www.vaultproject.io/api/secret/transit/index.html#generate-data-key) endpoint and [Decrypt Data](https://www.vaultproject.io/api/secret/transit/index.html#decrypt-data) endpoint. +Since KES sends object encryption keys to MinIO and Vault sends master keys (used to encrypt the object encryption keys) to KES we absolutely need +TLS connections between MinIO, KES and Vault. Therefore, we need to generate at least two TLS certificates. -**2.1.1 Start Vault server** +#### 2.1 Generate a TLS certificate for Vault -Vault requires access to `mlock` syscall by default. Use `setcap` to give the Vault executable the ability to use the `mlock` syscall without running the process as root. To do so run: +To generate a new private key for Vault's certificate run the following openssl command: +``` +openssl ecparam -genkey -name prime256v1 | openssl ec -out vault-tls.key +``` + +Then generate a new TLS certificate for the private/public key pair via: +``` +openssl req -new -x509 -days 365 -key vault-tls.key -out vault-tls.crt -subj "/C=US/ST=state/L=location/O=organization/CN=localhost" +``` +> You may want to adjust the X.509 subject (`-subj` parameter). Note that this is a self-signed certificate. For production deployments +> this certificate should be issued by a CA. + +#### 2.2 Generate a TLS certificate for KES + +To generate a new private key for KES's certificate run the following openssl command: +``` +openssl ecparam -genkey -name prime256v1 | openssl ec -out kes-tls.key +``` + +Then generate a new TLS certificate for the private/public key pair via: +``` +openssl req -new -x509 -days 365 -key kes-tls.key -out kes-tls.crt -subj "/C=US/ST=state/L=location/O=organization/CN=localhost" +``` +> You may want to adjust the X.509 subject (`-subj` parameter). Note that this is a self-signed certificate. For production deployments +> this certificate should be issued by a CA. + +#### 2.3 Generate a TLS certificate for MinIO (Optional) + +This step is optional. However, we recommend to up/download your S3 objects via TLS - especially when they should be encrypted at the +storage backend with a KMS. + +Checkout the [MinIO TLS guide](https://docs.min.io/docs/how-to-secure-access-to-minio-server-with-tls.html) for configuring MinIO and TLS. + +### 3 Set up Vault + +On unix-like systems, Vault uses the `mlock` syscall to prevent the OS from writing in-memory data +to disk (swapping). Therefore, you should give the Vault executable the ability to use the `mlock` +syscall without running the process as root. To do so run: ``` sudo setcap cap_ipc_lock=+ep $(readlink -f $(which vault)) ``` -Create `vault-config.json` to use file backend and start the server. +Then create the Vault config file: ``` cat > vault-config.json < vault-config.json < Note that we run Vault with a file backend. For high-availability you may want to use a different +> backend - like [etcd](https://www.vaultproject.io/docs/configuration/storage/etcd/) or [consul](https://learn.hashicorp.com/vault/operations/ops-vault-ha-consul). -vault server -config vault-config.json +Finally, start the Vault server via: ``` +vault server -config vault-config.json +``` -> NOTE: In this example we use `"tls_disable": true` for demonstration purposes only, -> in production setup you should generate proper TLS certificates by specifying -> - [`tls_cert_file`](https://www.vaultproject.io/docs/configuration/listener/tcp.html#tls_cert_file) -> - [`tls_key_file`](https://www.vaultproject.io/docs/configuration/listener/tcp.html#tls_key_file) +#### 3.1 Initialize and unseal Vault +In a separate terminal window set the `VAULT_ADDR` env. variable to your Vault server: +``` +export VAULT_ADDR='https://127.0.0.1:8200' +``` -**2.1.2 Initialize vault and unseal it** +Further, you may want to run `export VAULT_SKIP_VERIFY=true` if Vault uses a self-signed TLS +certificate. When Vault serves a TLS certificate that has been issued by a CA that is trusted +by your machine - e.g. Let's Encrypt - then you don't need to run this command. +Then initialize Vault via: ``` -export VAULT_ADDR='http://127.0.0.1:8200' vault operator init +``` + +Vault will print `n` (5 by default) unseal key shares of which at least `m` (3 by default) +are required to regenerate the actual unseal key to unseal Vault. Therefore, make sure to +remember them. In particular, keep those unseal key shares at a secure and durable location. + +You should see some output similar to: +``` Unseal Key 1: eyW/+8ZtsgT81Cb0e8OVxzJAQP5lY7Dcamnze+JnWEDT Unseal Key 2: 0tZn+7QQCxphpHwTm6/dC3LpP5JGIbYl6PK8Sy79R+P2 Unseal Key 3: cmhs+AUMXUuB6Lzsvgcbp3bRT6VDGQjgCBwB2xm0ANeF @@ -102,148 +202,243 @@ It is possible to generate new unseal keys, provided you have a quorum of existing unseal keys shares. See "vault operator rekey" for more information. ``` -Use any of the previously generated keys to unseal the vault +Now, set the env. variable `VAULT_TOKEN` to the root token printed by the command before: +``` +export VAULT_TOKEN=s.zaU4Gbcu0Wh46uj2V3VuUde0 +``` + +Then use any of the previously generated key shares to unseal Vault. ``` vault operator unseal eyW/+8ZtsgT81Cb0e8OVxzJAQP5lY7Dcamnze+JnWEDT vault operator unseal 0tZn+7QQCxphpHwTm6/dC3LpP5JGIbYl6PK8Sy79R+P2 vault operator unseal cmhs+AUMXUuB6Lzsvgcbp3bRT6VDGQjgCBwB2xm0ANeF -Key Value ---- ----- -Seal Type shamir -Initialized true -Sealed false ---> NOTE: vault is unsealed -Total Shares 5 -Threshold 3 -Version 1.1.3 -Cluster Name vault-cluster-3f084948 -Cluster ID 8c92e999-7062-4da6-4434-0fc05f34824d -HA Enabled false ``` -Obtain root token from the `vault operator init` output above. It is displayed as `Initial Root Token: s.zaU4Gbcu0Wh46uj2V3VuUde0` +Once you have submitted enough valid key shares Vault will become unsealed +and able to process requests. -**2.1.3 Set up vault transit backend and create an app role** +#### 3.2 Enable Vault's K/V backend + +The cryptographic master keys (but not the object encryption keys) will be stored +at Vault. Therefore, we need to enable Vault's K/V backend. To do so run: +``` +vault secrets enable kv ``` -export VAULT_TOKEN=s.zaU4Gbcu0Wh46uj2V3VuUde0 -vault auth enable approle # enable approle style auth -vault secrets enable transit # enable transit secrets engine -# define an encryption key-ring for the transit path -vault write -f transit/keys/my-minio-key +#### 3.3 Enable AppRole authentication -cat > vaultpolicy.hcl < minio-kes-policy.hcl < Observe the path-prefix `minio` in `kv/minio/*`. This prefix ensures that the +> KES server can only read from and write to entries under `minio/*` - but not under +> `some-app/*`. How to separate domains on the K/V engine depends on your infrastructure +> and security requirements. -# define a policy for AppRole to access transit path -vault policy write minio-policy ./vaultpolicy.hcl +Then we upload the policy to Vault: +``` +vault policy write minio-key-policy ./minio-kes-policy.hcl +``` -# period indicates it is renewable if token is renewed before the period is over -vault write auth/approle/role/my-role token_num_uses=0 secret_id_num_uses=0 period=5m +#### 3.5 Create an new AppRole ID and bind it to a policy -# define an AppRole -vault write auth/approle/role/my-role policies=minio-policy # apply policy to role -vault read auth/approle/role/my-role/role-id # get Approle ID -Key Value ---- ----- -role_id 8c03926c-6c51-7a1d-cf7d-62e48ab8d6d7 +Now, we need to create a new AppRole ID and grant that ID specific permissions. +The application (i.e. KES server) will authenticate to Vault via the AppRole role ID +and secret ID and is only allowed to perform operations granted by the specific policy. -vault write -f auth/approle/role/my-role/secret-id -Key Value ---- ----- -secret_id edd8738c-6efe-c226-74f9-ef5b66e119d7 -secret_id_accessor 57d1db64-6350-c321-4a3e-fc6aeb7d00b6 +So, we first create a new role for our KES server: +``` +vault write auth/approle/role/kes-role token_num_uses=0 secret_id_num_uses=0 period=5m ``` -The AppRole ID, AppRole Secret Id, Vault endpoint and Vault key name can now be used to start minio server with Vault as KMS. - -**2.1.3 Vault Environment variables** +Then we bind a policy to the role: +``` +vault write auth/approle/role/kes-role policies=minio-key-policy +``` -You'll need the Vault endpoint, AppRole ID, AppRole SecretID and encryption key-ring name defined in step 2.1.2 +Finally, we request an AppRole role ID and secret ID from Vault. +First, the role ID: +``` +vault read auth/approle/role/kes-role/role-id +``` +Then the secret ID: ``` -export MINIO_KMS_VAULT_APPROLE_ID=8c03926c-6c51-7a1d-cf7d-62e48ab8d6d7 -export MINIO_KMS_VAULT_APPROLE_SECRET=edd8738c-6efe-c226-74f9-ef5b66e119d7 -export MINIO_KMS_VAULT_ENDPOINT=http://vault-endpoint-ip:8200 -export MINIO_KMS_VAULT_KEY_NAME=my-minio-key -export MINIO_KMS_VAULT_AUTH_TYPE=approle -minio server ~/export +vault write -f auth/approle/role/kes-role/secret-id ``` +> We are only interested in the `secret_id` - not in the `secret_id_accessor`. -Optionally, set `MINIO_KMS_VAULT_CAPATH` to a directory of PEM-encoded CA cert files to use mTLS for client-server authentication. +### 4 Set up KES +Similar to Vault, KES uses the `mlock` syscall on linux systems to prevent the OS from writing in-memory +data to disk (swapping). Therefore, you should give the KES executable the ability to use the `mlock` +syscall without running the process as root. To do so run: ``` -export MINIO_KMS_VAULT_CAPATH=/home/user/custom-certs +sudo setcap cap_ipc_lock=+ep $(readlink -f $(which kes)) ``` -An additional option is to set `MINIO_KMS_VAULT_NAMESPACE` if AppRole and Transit Secrets engine have been scoped to Vault Namespace +#### 4.1 Create an identity for MinIO + +Each user or application must present a valid X.509 certificate when connecting to the KES server (mTLS). +The KES server will accept/reject the connection attempt and applies policies based on the certificate. +Therefore, each MinIO cluster needs a X.509 TLS certificate for client authentication. You can create a +(self-signed) certificate by running: ``` -export MINIO_KMS_VAULT_NAMESPACE=ns1 +kes tool identity new MinIO --key=minio.key --cert=minio.cert --time=8760h ``` +> Note that *MinIO* is the [subject name](https://en.wikipedia.org/wiki/X.509#Structure_of_a_certificate). +> You may choose a more appropriate name for your deployment scenario. Also, for production deployments we +> recommend to get a TLS certificate for client authentication that has been issued by a CA. -Note: If [Vault Namespaces](https://learn.hashicorp.com/vault/operations/namespaces) are in use, MINIO_KMS_VAULT_VAULT_NAMESPACE variable needs to be set before setting approle and transit secrets engine. +To get the identity of a X.509 certificate run: +``` +kes tool identity of minio.cert +``` +> This command works with any (valid) X.509 certificate - regardless how it has been created - and +> produces an output similar to: +
+

Identity: dd46485bedc9ad2909d2e8f9017216eec4413bc5c64b236d992f7ec19c843c5f

+
-#### 2.2 Specify a master key +#### 4.2 Create the KES config file -**2.2.1 KMS master key from environment variables** +Now, we can create the KES config file and start the KES server. +``` +cat > kes-config.toml < Please change the value of `identities` under `policy.minio` to the identity of your `minio.cert`. +> Also, insert the AppRole role ID and secret ID that you have created previously during the Vault setup. +> You can find a documented config file with all available parameters [here](https://github.com/minio/kes/blob/master/server-config.toml). + +Finally, start the KES server via: ``` +kes server --config=kes-config.toml --mlock --root=disabled --mtls-auth=ignore +``` +> Note that we effectively disable the special *root* identity since we don't need it. +> For more information about KES identities checkout: [KES Identities](https://github.com/minio/kes/wiki#identities) +> Further, note that we pass `--mtls-auth=ignore` since the client X.509 certificate +> is a self-signed certificate. + +#### 4.3 Create a new master key -Please use your own master key. A random master key can be generated using e.g. this command on Linux/Mac/BSD* systems: +Before we can proceed with the MinIO setup we need to create a new master key. Therefore we use the +MinIO identity and the KES CLI. +In a new terminal window become the MinIO identity via: ``` -head -c 32 /dev/urandom | xxd -c 32 -ps +export KES_CLIENT_TLS_KEY_FILE=minio.key +export KES_CLIENT_TLS_CERT_FILE=minio.cert ``` -**2.2.2 KMS master key from docker secret** +Then create the master key by running: +``` +kes key create minio-key-1 -k +``` +> The `-k` flag is only required since we use self-signed certificates. +> Also, observe that based on the server config file the MinIO identity +> is only allowed to create/use master keys that start with `minio-`. +> So, trying to create a key e.g. `kes key create my-key-1 -k` will +> fail with a *prohibited by policy* error. -Alternatively, you may pass a master key as a [Docker secret](https://docs.docker.com/engine/swarm/secrets/). +### 5 Set up the MinIO server -```bash -echo "my-minio-key:6368616e676520746869732070617373776f726420746f206120736563726574" | docker secret create kms_master_key +The MinIO server will need to know the KES server endpoint, its mTLS client certificate +for authentication and authorization and the default master key name. + +``` +export MINIO_KMS_KES_ENDPOINT=https://localhost:7373 +export MINIO_KMS_KES_KEY_FILE=minio.key +export MINIO_KMS_KES_CERT_FILE=minio.cert +export MINIO_KMS_KES_KEY_NAME=minio-key-1 +export MINIO_KMS_KES_CAPATH=kes-tls.crt ``` +> The `MINIO_KMS_KES_CAPATH` is only required since we use self-signed certificates. -Obviously, do not use this demo key for anything real! +Optionally, enable auto-encryption to encrypt uploaded objects automatically: +``` +export MINIO_KMS_AUTO_ENCRYPTION=on +``` +> For more information about auto-encryption see: [Appendix A](#appendix-a---auto-encryption) -To use another secret name, follow the instructions above and replace kms_master_key with your custom names (e.g. my_kms_master_key). Then, set the MINIO_KMS_MASTER_KEY_FILE environment variable to your secret name: +Then start the MinIO server: -```bash -export MINIO_KMS_MASTER_KEY_FILE=my_kms_master_key +``` +export MINIO_ACCESS_KEY=minio +export MINIO_SECRET_KEY=minio123 ``` -### 3. Test your setup -To test this setup, start minio server with environment variables set in Step 3, and server is ready to handle SSE-S3 requests. +``` +minio server ~/export +``` -### Auto-Encryption +### Appendix A - Auto-Encryption -MinIO can also enable auto-encryption **if** a valid KMS configuration is specified and the storage backend supports -encrypted objects. Auto-Encryption, if enabled, ensures that all uploaded objects are encrypted using the specified -KMS configuration. +Optionally, you can instruct the MinIO server to automatically encrypt all objects with keys from the KES +server - even if the client does not specify any encryption headers during the S3 PUT operation. -Auto-Encryption is useful especially if the MinIO operator wants to ensure that objects are **never** stored in -plaintext - for example if sensitive data is stored on public cloud storage. +Auto-Encryption is especially useful when the MinIO operator wants to ensure that all data stored on MinIO +gets encrypted before it's written to the storage backend. To enable auto-encryption set the environment variable to `on`: - ``` export MINIO_KMS_AUTO_ENCRYPTION=on ``` +> Note that auto-encryption only affects requests without S3 encryption headers. So, if a S3 client sends +> e.g. SSE-C headers, MinIO will encrypt the object with the key sent by the client and won't reach out to +> the KMS. + To verify auto-encryption, use the `mc` command: ``` @@ -256,10 +451,40 @@ Encrypted : X-Amz-Server-Side-Encryption: AES256 ``` -Note: Auto-Encryption only affects non-SSE-C requests since objects uploaded using SSE-C are already encrypted -and S3 only allows either SSE-S3 or SSE-C but not both for the same object. +### Appendix B - Specify a master key + +Instead of a proper KMS setup you can also **test** MinIO encryption using a KMS master key. +**A single master key via env. variable is for testing purposes only and not recommended for production deployments.** + +A KMS master key consists of a master-key ID (CMK) and the 256 bit master key encoded as HEX value separated by a `:`. +A KMS master key can be specified directly using: + +``` +export MINIO_KMS_MASTER_KEY=minio-demo-key:6368616e676520746869732070617373776f726420746f206120736563726574 +``` + +Please use your own master key. A random master key can be generated using e.g. this command on Linux/Mac/BSD systems: + +``` +head -c 32 /dev/urandom | xxd -c 32 -ps +``` + +*** + +Alternatively, you may pass a master key as a [Docker secret](https://docs.docker.com/engine/swarm/secrets/). + +```bash +echo "my-minio-key:6368616e676520746869732070617373776f726420746f206120736563726574" | docker secret create kms_master_key +``` + +To use another secret name, follow the instructions above and replace `kms_master_key` with your custom names (e.g. `my_kms_master_key`). +Then, set the `MINIO_KMS_MASTER_KEY_FILE` environment variable to your secret name: + +```bash +export MINIO_KMS_MASTER_KEY_FILE=my_kms_master_key +``` -# Explore Further +## Explore Further - [Use `mc` with MinIO Server](https://docs.min.io/docs/minio-client-quickstart-guide) - [Use `aws-cli` with MinIO Server](https://docs.min.io/docs/aws-cli-with-minio) diff --git a/docs/kms/kes-config.toml b/docs/kms/kes-config.toml new file mode 100644 index 000000000..5083d5717 --- /dev/null +++ b/docs/kms/kes-config.toml @@ -0,0 +1,33 @@ +# The address:port of the kes server - i.e. on the local machine. +address = "127.0.0.1:7373" + +[tls] +key = "./kes-tls.key" +cert = "./kes-tls.crt" + +[policy.minio] +paths = [ + "/v1/key/create/minio-*", + "/v1/key/generate/minio-*", + "/v1/key/decrypt/minio-*" + ] +identities = [ "dd46485bedc9ad2909d2e8f9017216eec4413bc5c64b236d992f7ec19c843c5f" ] + +[cache.expiry] +all = "5m" +unused = "20s" + +[keystore.vault] +address = "https://127.0.0.1:8200" # The Vault endpoint - i.e. https://127.0.0.1:8200 +name = "minio" # The domain resp. prefix at Vault's K/V backend + +[keystore.vault.approle] +id = "" # Your AppRole Role ID +secret = "" # Your AppRole Secret ID +retry = "15s" # Duration until the server tries to re-authenticate after connection loss. + +[keystore.vault.tls] +ca = "./vault-tls.crt" # Since we use self-signed certificates + +[keystore.vault.status] +ping = "10s" diff --git a/docs/kms/vault-config.json b/docs/kms/vault-config.json index f0da82c1a..3020c8792 100644 --- a/docs/kms/vault-config.json +++ b/docs/kms/vault-config.json @@ -1,5 +1,5 @@ { - "api_addr": "http://127.0.0.1:8200", + "api_addr": "https://127.0.0.1:8200", "backend": { "file": { "path": "vault/file" @@ -10,8 +10,9 @@ "listener": { "tcp": { "address": "0.0.0.0:8200", - "tls_disable": true + "tls_cert_file": "vault-tls.crt", + "tls_key_file": "vault-tls.key", + "tls_min_version": "tls12" } - }, - "ui": true + } } diff --git a/docs/kms/vault-legacy.md b/docs/kms/vault-legacy.md new file mode 100644 index 000000000..eb12aa7a3 --- /dev/null +++ b/docs/kms/vault-legacy.md @@ -0,0 +1,269 @@ +# KMS Quickstart Guide [![Slack](https://slack.min.io/slack?type=svg)](https://slack.min.io) + +MinIO uses a key-management-system (KMS) to support SSE-S3. If a client requests SSE-S3, or auto-encryption +is enabled, the MinIO server encrypts each object with an unique object key which is protected by a master key +managed by the KMS. Usually all object keys are protected by a single master key. + +MinIO supports two different KMS concepts: + - External KMS: + MinIO can be configured to use an external KMS i.e. [Hashicorp Vault](https://www.vaultproject.io/). + An external KMS decouples MinIO as storage system from key-management. An external KMS can + be managed by a dedicated security team and allows you to grant/deny access to (certain) objects + by enabling or disabling the corresponding master keys on demand. + +- Direct KMS master keys: + MinIO can also be configured to directly use a master key specified by the environment variable `MINIO_KMS_MASTER_KEY` or with a docker secret key. + Direct master keys are useful if the storage backend is not on the same machine as the MinIO server, e.g., + if network drives or MinIO gateway is used and an external KMS would cause too much management overhead. + + Note: KMS master keys are mainly for testing purposes. It's not recommended to use them for production deployments. + Further if the MinIO server machine is ever compromised, then the master key must also be treated as compromised. + +**Important:** +If multiple MinIO servers are configured as [gateways](https://github.com/minio/minio/blob/master/docs/gateway/README.md) pointing to the *same* backend - for example the same NAS storage - then the KMS configuration **must** be the same for all gateways. Otherwise one gateway may not be able to decrypt objects created by another gateway. It is the operator responsibility to ensure consistency. + +## Get started + +### 1. Prerequisites +Install MinIO - [MinIO Quickstart Guide](https://docs.min.io/docs/minio-quickstart-guide). + +### 2. Setup a KMS + +Either use Hashicorp Vault as external KMS or specify a master key directly depending on your use case. + +#### 2.1 Setup Hashicorp Vault + +Here is a sample quick start for configuring vault with a transit backend and Approle with correct policy + +MinIO requires the following Vault setup: +- The [transit backend](https://www.vaultproject.io/api/secret/transit/index.html) configured with a named encryption key-ring +- [AppRole](https://www.vaultproject.io/docs/auth/approle.html) based authentication with read/update policy for transit backend. In particular, read and update policy are required for the [Generate Data Key](https://www.vaultproject.io/api/secret/transit/index.html#generate-data-key) endpoint and [Decrypt Data](https://www.vaultproject.io/api/secret/transit/index.html#decrypt-data) endpoint. + +**2.1.1 Start Vault server** + +Vault requires access to `mlock` syscall by default. Use `setcap` to give the Vault executable the ability to use the `mlock` syscall without running the process as root. To do so run: +``` +sudo setcap cap_ipc_lock=+ep $(readlink -f $(which vault)) +``` + +Create `vault-config.json` to use file backend and start the server. +``` +cat > vault-config.json < NOTE: In this example we use `"tls_disable": true` for demonstration purposes only, +> in production setup you should generate proper TLS certificates by specifying +> - [`tls_cert_file`](https://www.vaultproject.io/docs/configuration/listener/tcp.html#tls_cert_file) +> - [`tls_key_file`](https://www.vaultproject.io/docs/configuration/listener/tcp.html#tls_key_file) + + +**2.1.2 Initialize vault and unseal it** + +``` +export VAULT_ADDR='http://127.0.0.1:8200' +vault operator init +Unseal Key 1: eyW/+8ZtsgT81Cb0e8OVxzJAQP5lY7Dcamnze+JnWEDT +Unseal Key 2: 0tZn+7QQCxphpHwTm6/dC3LpP5JGIbYl6PK8Sy79R+P2 +Unseal Key 3: cmhs+AUMXUuB6Lzsvgcbp3bRT6VDGQjgCBwB2xm0ANeF +Unseal Key 4: /fTPpec5fWpGqWHK+uhnnTNMQyAbl5alUi4iq2yNgyqj +Unseal Key 5: UPdDVPto+H6ko+20NKmagK40MOskqOBw4y/S51WpgVy/ + +Initial Root Token: s.zaU4Gbcu0Wh46uj2V3VuUde0 + +Vault is initialized with 5 key shares and a key threshold of 3. Please securely +distribute the key shares printed above. When the Vault is re-sealed, +restarted, or stopped, you must supply at least 3 of these keys to unseal it +before it can start servicing requests. + +Vault does not store the generated master key. Without at least 3 key to +reconstruct the master key, Vault will remain permanently sealed! + +It is possible to generate new unseal keys, provided you have a quorum of +existing unseal keys shares. See "vault operator rekey" for more information. +``` + +Use any of the previously generated keys to unseal the vault +``` +vault operator unseal eyW/+8ZtsgT81Cb0e8OVxzJAQP5lY7Dcamnze+JnWEDT +vault operator unseal 0tZn+7QQCxphpHwTm6/dC3LpP5JGIbYl6PK8Sy79R+P2 +vault operator unseal cmhs+AUMXUuB6Lzsvgcbp3bRT6VDGQjgCBwB2xm0ANeF +Key Value +--- ----- +Seal Type shamir +Initialized true +Sealed false ---> NOTE: vault is unsealed +Total Shares 5 +Threshold 3 +Version 1.1.3 +Cluster Name vault-cluster-3f084948 +Cluster ID 8c92e999-7062-4da6-4434-0fc05f34824d +HA Enabled false +``` + +Obtain root token from the `vault operator init` output above. It is displayed as `Initial Root Token: s.zaU4Gbcu0Wh46uj2V3VuUde0` + +**2.1.3 Set up vault transit backend and create an app role** +``` +export VAULT_TOKEN=s.zaU4Gbcu0Wh46uj2V3VuUde0 + +vault auth enable approle # enable approle style auth +vault secrets enable transit # enable transit secrets engine +# define an encryption key-ring for the transit path +vault write -f transit/keys/my-minio-key + +cat > vaultpolicy.hcl <