Vault agent and Vault proxy Auto-Auth
The Auto-Auth functionality of Vault Agent and Vault Proxy allow for easy authentication in a wide variety of environments.
Functionality
Auto-Auth consists of two parts: a Method, which is the authentication method that should be used in the current environment; and any number of Sinks, which are locations where the agent should write a token any time the current token value has changed.
When Vault Agent or Vault Proxy are started with Auto-Auth enabled, it will attempt to acquire a Vault token using the configured Method. On failure, it will exponentially back off and then retry. On success, unless the auth method is configured to wrap the tokens, it will keep the resulting token renewed until renewal is no longer allowed or fails, at which point it will attempt to reauthenticate.
Every time an authentication is successful, the token is written to the configured Sinks, subject to their configuration.
Advanced functionality
Sinks support some advanced features, including the ability for the written values to be encrypted or response-wrapped.
Both mechanisms can be used concurrently; in this case, the value will be response-wrapped, then encrypted.
Response-Wrapping tokens
There are two ways that tokens can be response-wrapped:
By the auth method. This allows the end client to introspect the
creation_path
of the token, helping prevent Man-In-The-Middle (MITM) attacks. However, because auto-auth cannot then unwrap the token and rewrap it without modifying thecreation_path
, we are not able to renew the token; it is up to the end client to renew the token. Agent and Proxy both stay daemonized in this mode since some auth methods allow for reauthentication on certain events.By any of the token sinks. Because more than one sink can be configured, the token must be wrapped after it is fetched, rather than wrapped by Vault as it's being returned. As a result, the
creation_path
will always besys/wrapping/wrap
, and validation of this field cannot be used as protection against MITM attacks. However, this mode allows auto-auth to keep the token renewed for the end client and automatically reauthenticate when it expires.
Encrypting tokens
Support for encrypted tokens is experimental; if input/output formats change, we will make every effort to provide backwards compatibility.
Tokens can be encrypted, using a Diffie-Hellman exchange to generate an ephemeral key. In this mechanism, the client receiving the token writes a generated public key to a file. The sink responsible for writing the token to that client looks for this public key and uses it to compute a shared secret key, which is then used to encrypt the token via AES-GCM. The nonce, encrypted payload, and the sink's public key are then written to the output file, where the client can compute the shared secret and decrypt the token value.
NOTE: Token encryption is not a protection against MITM attacks! The purpose of this feature is for forward-secrecy and coverage against bare token values being persisted. A MITM that can write to the sink's output and/or client public-key input files could attack this exchange. Using TLS to protect the transit of tokens is highly recommended.
To help mitigate MITM attacks, additional authenticated data (AAD) can be provided to Agent and Proxy. This data is written as part of the AES-GCM tag and must match on both Agent and Proxy and the client. This of course means that protecting this AAD becomes important, but it provides another layer for an attacker to have to overcome. For instance, if the attacker has access to the file system where the token is being written, but not to read configuration or read environment variables, this AAD can be generated and passed to Agent or Proxy and the client in ways that would be difficult for the attacker to find.
When using AAD, it is always a good idea for this to be as fresh as possible; generate a value and pass it to your client and Agent or Proxy on startup. Additionally, Agent and Proxy a Trust On First Use model; after it finds a generated public key, it will reuse that public key instead of looking for new values that have been written.
If writing a client that uses this feature, it will likely be helpful to look at the dhutil library. This shows the expected format of the public key input and envelope output formats.
Configuration
The top level auto_auth
block has two configuration entries:
method
(object: required)
- Configuration for the methodsinks
(array of objects: optional)
- Configuration for the sinks
Configuration (Method)
Auto-auth does not support using tokens with a limited number of uses. Auto-auth
does not track the number of uses remaining, and may allow the token to
expire before attempting to renew it. For example, if using AppRole auto-auth,
you must use 0 (meaning unlimited) as the value for
token_num_uses
.
These are common configuration values that live within the method
block:
type
(string: required)
- The type of the method to use, e.g.aws
,gcp
,azure
, etc. Note: when using HCL this can be used as the key for the block, e.g.method "aws" {...}
.mount_path
(string: optional)
- The mount path of the method. If not specified, defaults to a value ofauth/<method type>
.namespace
(string: optional)
- Namespace in which the mount lives. The order of precedence is: this setting lowest, followed by the environment variableVAULT_NAMESPACE
, and then the highest precedence command-line option-namespace
. If none of these are specified, defaults to the root namespace. Note that because sink response wrapping and templating are also based on the client created by auto-auth, they use the same namespace.wrap_ttl
(string or integer: optional)
- If specified, the written token will be response-wrapped by auto-auth. This is more secure than wrapping by sinks, but does not allow the auto-auth to keep the token renewed or automatically reauthenticate when it expires. Rather than a simple string, the written value will be a JSON-encoded SecretWrapInfo structure. Uses duration format strings.min_backoff
(string or integer: "1s")
- The minimum backoff time auto-auth will delay before retrying after a failed auth attempt. The backoff will start at the configured value and double (with some randomness) after successive failures, capped bymax_backoff.
If Agent templating is being used, this value is also used as the min backoff time for the templating server. Uses duration format strings.max_backoff
(string or integer: "5m")
- The maximum time Agent will delay before retrying after a failed auth attempt. The backoff will start atmin_backoff
and double (with some randomness) after successive failures, capped bymax_backoff.
If Agent templating is being used, this value is also used as the max backoff time for the templating server.max_backoff
is the duration between retries, and not the duration that retries will be performed before giving up. Uses duration format strings.exit_on_err
(bool: false)
- When set to true, Vault Agent and Vault Proxy will exit if any errors occur during authentication. This configurable only affects login attempts for new tokens (either initial or expired tokens) and will not exit for errors on valid token renewals.config
(object: required)
- Configuration of the method itself. See the sidebar for information about each method.
Configuration (Sinks)
These configuration values are common to all Sinks:
type
(string: required)
- The type of the method to use, e.g.file
. Note: when using HCL this can be used as the key for the block, e.g.sink "file" {...}
.wrap_ttl
(string or integer: optional)
- If specified, the written token will be response-wrapped by the sink. This is less secure than wrapping by the method, but allows auto-auth to keep the token renewed and automatically reauthenticate when it expires. Rather than a simple string, the written value will be a JSON-encoded SecretWrapInfo structure. Uses duration format strings.dh_type
(string: optional)
- If specified, the type of Diffie-Hellman exchange to perform, meaning, which ciphers and/or curves. Currently onlycurve25519
is supported.dh_path
(string: required if dh_type is set)
- The path from which the auto-auth should read the client's initial parameters (e.g. curve25519 public key).derive_key
(bool: false)
- If specified, the final encryption key is calculated by using HKDF-SHA256 to derive a key from the calculated shared secret and the two public keys for enhanced security. This is recommended if backward compatibility isn't a concern.aad
(string: optional)
- If specified, additional authenticated data to use with the AES-GCM encryption of the token. Can be any string, including serialized data.aad_env_var
(string: optional)
- If specified, AAD will be read from the given environment variable rather than a value in the configuration file.config
(object: required)
- Configuration of the sink itself. See the sidebar for information about each sink.
Auto auth examples
Auto-Auth configuration objects take two separate forms when specified in HCL and JSON. The following examples are meant to clarify the differences between the two formats.
Sinks (HCL format)
The HCL format may define any number of sink objects with an optional wrapping
sinks {...}
object.
Note: The corresponding JSON format must specify a
"sinks" : [...]
array to encapsulate all sink
JSON objects.
The following valid HCL omits the wrapping sinks
object while specifying
multiple sinks.
Sinks (JSON format)
The following JSON configuration illustrates the need for a sinks: [...]
array
wrapping any number of sink
objects.
Multiple sinks are defined by appending more sink
objects within the sinks
array: