Consul
core
Overview
Consul enables automation of network configurations, service discovery, and secure network connectivity across any cloud or runtime.
Consul uses a lightweight gossip and RPC system which provides various essential features. Both of these systems provide security mechanisms which should be used to enable confidentiality, integrity and authentication.
Using defense in depth is crucial for Consul security, and deployment requirements may differ drastically depending on your use case. Some security features for multi-tenant deployments are offered exclusively in the Enterprise version. This documentation may need to be adapted to your environment, but the general mechanisms for a secure Consul deployment revolve around:
mTLS - Mutual authentication of both the TLS server and client x509 certificates prevents internal abuse from unauthorized access to network components within the cluster.
ACLs - Enable role-based access controls for authenticated connections by granting capabilities for an individual human, or machine operator identity via an ACL token to authorize actions within a cluster. Optionally, custom authentication methods can be used to enable trusted external parties to authorize ACL token creation.
Intentions - If in use, configure service intentions to use a default-deny policy. If L7 intentions are in use, enable Mesh request normalization and review your header match rules to prevent malformed requests from bypassing intentions.
Namespaces Enterprise - Read and write operations can be scoped to a logical namespace to restrict access to Consul components within a multi-tenant environment.
Sentinel Policies Enterprise - Sentinel policies enable policy-as-code for granular control over the built-in key-value store.
Personas
It helps to consider the following types of personas when managing the security requirements of a Consul deployment. The granularity may change depending on your team's requirements.
System Administrator - This is someone who has access to the underlying infrastructure to the Consul cluster. Often they have access to SSH or RDP directly into a server within a cluster through a bastion host. Ultimately they have read, write and execute permissions for the actual Consul binary. This binary is the same for server and client agents using different configuration files. These users potentially have sudo, administrative, or some other super-user access to the underlying compute resource. They have access to all persisted data on disk, or in memory. This would include ACL tokens, certificates, and other secrets stored on the system. Users like these are essentially totally trusted, as they have administrative rights to the underlying operating-system with the ability to configure, start, and stop the agent.
Consul Administrator - This is someone (probably the same System Administrator) who has access to define the Consul agent configurations for servers and clients, and/or have a Consul management ACL token. They also have total rights to all of the parts in the Consul system including the ability to manage all services within a cluster.
Consul Operator - This is someone who likely has restricted capabilities to use their namespace within a cluster.
Developer - This is someone who is responsible for creating, and possibly deploying applications connected, or configured with Consul. In some cases they may have no access, or limited capabilities to view Consul information, such as through metrics, or logs.
User - This is the end user, using applications backed by services managed by Consul. In some cases services may be public facing on the internet such as a web server, typically through a load-balancer, or ingress gateway. This is someone who should not have any network access to the Consul agent APIs.
Secure Configuration
Consul's security model is applicable only if all parts of the system are running with a secure configuration; Consul is not secure-by-default. Without the following mechanisms enabled in Consul's configuration, it may be possible to abuse access to a cluster. Like all security considerations, administrators must determine what is appropriate for their environment and adapt these configurations accordingly.
Requirements
mTLS - Mutual authentication of both the TLS server and client x509 certificates prevents internal abuse through unauthorized access to Consul agents within the cluster.
tls.defaults.verify_incoming
- By default this is false, and should almost always be set to true to require TLS verification for incoming client connections. This applies to the internal RPC, HTTPS and gRPC APIs.tls.https.verify_incoming
- By default this is false, and should be set to true to require clients to provide a valid TLS certificate when the Consul HTTPS API is enabled. TLS for the API may be not be necessary if it is exclusively served over a loopback interface such aslocalhost
.tls.internal_rpc.verify_incoming
- By default this is false, and should almost always be set to true to require clients to provide a valid TLS certificate for Consul agent RPCs.tls.grpc.verify_incoming
- By default this is false, and should be set to true to require clients to provide a valid TLS certificate when the Consul gRPC API is enabled. TLS for the API may be not be necessary if it is exclusively served over a loopback interface such aslocalhost
.tls.internal_rpc.verify_outgoing
- By default this is false, and should be set to true to require TLS for outgoing connections from server or client agents. Servers that specifyverify_outgoing = true
will always talk to other servers over TLS, but they still accept non-TLS connections to allow for a transition of all clients to TLS. Currently the only way to enforce that no client can communicate with a server unencrypted is to also enableverify_incoming
which requires client certificates too.enable_agent_tls_for_checks
- By default this is false, and should almost always be set to true to require mTLS to set up the client for HTTP or gRPC health checks. This was added in Consul 1.0.1.tls.internal_rpc.verify_server_hostname
- By default this is false, and should be set to true to require that the TLS certificate presented by the servers matchesserver.<datacenter>.<domain>
hostname for outgoing TLS connections. The default configuration does not verify the hostname of the certificate, only that it is signed by a trusted CA. This setting is critical to prevent a compromised client agent from being restarted as a server and having all cluster state including all ACL tokens and service mesh CA root keys replicated to it. This setting was introduced in 0.5.1. From version 0.5.1 to 1.4.0 we documented thatverify_server_hostname
being true implied verify_outgoing however due to a bug this was not the case so setting onlyverify_server_hostname
results in plaintext communication between client and server. See CVE-2018-19653 for more details. This is fixed in 1.4.1.auto_encrypt
- Enables automated TLS certificate distribution for client agent RPC communication using the service mesh CA. Using this configuration aca_file
and ACL token would still need to be distributed to client agents.allow_tls
- By default this is false, and should be set to true on server agents to allow certificates to be automatically generated and distributed from the service mesh CA to client agents.tls
- By default this is false, and should be set to true on client agents to automatically request a client TLS certificate from the server's service mesh CA.
Example Server Agent TLS Configuration
tls { defaults { verify_incoming = true verify_outgoing = true ca_file = "consul-agent-ca.pem" cert_file = "dc1-server-consul-0.pem" key_file = "dc1-server-consul-0-key.pem" verify_server_hostname = true } } auto_encrypt { allow_tls = true }
Example Client Agent TLS Configuration
tls { defaults { verify_incoming = false verify_outgoing = true ca_file = "consul-agent-ca.pem" verify_server_hostname = true } } auto_encrypt { tls = true }
Note: The client agent TLS configuration from above sets
verify_incoming
to false which assumes all incoming traffic is restricted tolocalhost
. The primary benefit for this configuration would be to avoid provisioning client TLS certificates (in addition to ACL tokens) for all tools or applications using the local Consul agent. In this case ACLs should be enabled to provide authorization and only ACL tokens would need to be distributed.ACLs - The access control list (ACL) system provides a security mechanism for Consul administrators to grant capabilities tied to an individual human, or machine operator identity. To ultimately secure the ACL system, administrators should configure the
default_policy
to "deny".The system is comprised of five major components:
🗝 Token - API key associated with policies, roles, or service identities.
📜 Policy - Set of rules to grant or deny access to various Consul resources.
🎭 Role - Grouping of policies, and service identities.
👤 Service or Node Identity - Synthetic policy granting a predefined set of permissions typical for services deployed within Consul.
🏷 Namespace Enterprise - a named, logical scoping of Consul Enterprise resources, typically to enable multi-tenant environments. Consul CE clusters always operate within the "default" namespace.
Intentions - Service intentions control traffic communication between services at the network layer (L4) and application layer (L7). If in use, we strongly recommend configuring intentions to use a default-deny policy. When L7 intentions are in use, review your configuration for Mesh request normalization and use the strictest set of options suitable to your environment. At minimum, we recommend keeping path normalization enabled, because this default setting prevents requests that do not conform to RFC 3986 from bypassing path match rules.
Gossip Encryption - A shared, base64-encoded 32-byte symmetric key is required to encrypt Serf gossip communication within a cluster using AES GCM. The key size determines which AES encryption types to use; 16, 24, or 32 bytes to select AES-128, AES-192, or AES-256 respectively. 32-byte keys are ultimately preferable and is the default size generated by the
keygen
command. This key should be regularly rotated using the builtin keyring management features of Consul.Two optional gossip encryption options enable Consul servers without gossip encryption to safely upgrade. After upgrading, the verification options should be enabled, or removed to set them to their default state:
encrypt_verify_incoming
- By default this is true to enforce encryption on incoming gossip communications.encrypt_verify_outgoing
- By default this is true to enforce encryption on outgoing gossip communications.
Namespaces Enterprise - Read and write operations should be scoped to logical namespaces to restrict access to Consul components within a multi-tenant environment. Furthermore, this feature can be used to enable a self-service approach to Consul ACL administration for teams within a scoped namespace.
Sentinel Policies Enterprise - Sentinel policies allow for granular control over the builtin key-value store.
Ensure Script Checks are Disabled - Consul's agent optionally has an HTTP API, which can be exposed beyond
localhost
. If this is the case,enable_script_checks
must be false otherwise, even with ACLs configured, script checks present a remote code execution threat.enable_local_script_checks
provides a secure alternative if the HTTP API must be exposed and is available from 1.3.0 on. This feature was also back-ported to patch releases 0.9.4, 1.1.1, and 1.2.4 as described here. This is not enabled by default.Ensure Remote Execution is Disabled - Consul includes a consul exec feature allowing execution of arbitrary commands across the cluster. This is disabled by default since 0.8.0. We recommend leaving it disabled. If enabled, extreme care must be taken to ensure correct ACLs restrict access to execute arbitrary code on the cluster.
Recommendations
Rotate Credentials - Using short-lived credentials and rotating them frequently is highly recommended for production environments to limit the blast radius from potentially compromised secrets, and enabling basic auditing.
ACL Tokens - Consul APIs require an ACL token to authorize actions within a cluster.
X.509 Certificates - Rotate certificates used by the Consul agent; e.g. integrate with Vault's PKI secret engine to automatically generate and renew dynamic, unique X.509 certificates for each Consul node with a short TTL. Client certificates can be automatically rotated by Consul when using
auto_encrypt
such that only server certificates would be managed by Vault.Gossip Keys - Rotating the encryption keys used by the internal gossip protocol for Consul agents can be regularly rotated using the builtin keyring management features.
Running without Root - Consul agents can be run as unprivileged users that only require access to the data directory.
Linux Security Modules - Use of security modules that can be directly integrated into operating systems such as AppArmor, SElinux, and Seccomp on Consul agent hosts.
Customize TLS Settings - TLS settings such as the available cipher suites, should be tuned to fit the needs of your environment.
tls_min_version
- Used to specify the minimum TLS version to use.tls_cipher_suites
- Used to specify which TLS cipher suites are allowed.
Customize HTTP Response Headers - Additional security headers, such as
X-XSS-Protection
, can be configured for HTTP API responses.http_config { response_headers { "X-Frame-Options" = "DENY" } }
Customize Mesh HTTP Request Normalization - If L7 intentions are in use, we recommend configuring request normalization to avoid match rule circumvention. Other normalization options, such as dropping or rejecting headers with underscores, may also be appropriate depending on your requirements. Review the options in the Mesh configuration entry to determine the appropriate settings for your use case.
Customize Default Limits - Consul has a number of builtin features with default connection limits that should be tuned to fit your environment.
http_max_conns_per_client
- Used to limit concurrent access from a single client to the HTTP(S) endpoint on Consul agents.https_handshake_timeout
- Used to timeout TLS connection for the HTTP(S) endpoint for Consul agents.rpc_handshake_timeout
- Used to timeout TLS connections for the RPC endpoint for Consul agents.rpc_max_conns_per_client
- Used to limit concurrent access from a single client to the RPC endpoint on Consul agents.rpc_rate
- Disabled by default, this is used to limit (requests/second) for client agents making RPC calls to server agents.rpc_max_burst
- Used as the token bucket size for client agents making RPC calls to server agents.kv_max_value_size
- Used to configure the max number of bytes in a key-value API request.txn_max_req_len
- Used to configure the max number of bytes in a transaction API request.
Secure UI Access - Access to Consul's builtin UI can be secured in various ways:
mTLS - Enabling the HTTPS with mutual TLS authentication is recommended, but requires extra tooling to terminate the mTLS connection, preferably on an operator's local machine using a proxy script. To do this, follow the tutorial on Configuring the Consul UI for HTTPS and in Step 2 use "Option 1: add a client certificate to your browser".
TLS - Enabling the HTTPS is recommended where mTLS may not be required for UI access, such as when ACLs are configured with a default deny. To do this, follow the tutorial on Configuring the Consul UI for HTTPS and in Step 2 use "Option 2: verify_incoming_rpc".
ACL - ACLs with a default deny policy enables safer UI access by preventing unauthorized access to sensitive components within the cluster. To do this, follow the tutorial on Securing Consul with Access Control Lists (ACLs), which includes a section on creating ACL tokens that provide a desired level UI access.
Restrict HTTP Writes - Using the
allow_write_http_from
configuration option to restrict write access for agent endpoints to hosts on the specified list of CIDRs.Example Agent Configuration
http_config { allow_write_http_from = ["127.0.0.0/8"] }
Threat Model
The following are parts of the core Consul threat model:
Consul agent-to-agent communication - Communication between Consul agents should be secure from eavesdropping. This requires transport encryption to be enabled on the cluster and covers both TCP and UDP traffic.
Consul agent-to-CA communication - Communication between the Consul server and the configured certificate authority provider for service mesh is always encrypted.
Tampering of data in transit - Any tampering should be detectable and cause Consul to avoid processing the request.
Access to data without authentication or authorization - All requests must be authenticated and authorized. This requires that ACLs are enabled on the cluster with a default deny mode.
State modification or corruption due to malicious messages - Ill-formatted messages are discarded and well-formatted messages require authentication and authorization.
Non-server members accessing raw data - All servers must join the cluster (with proper authentication and authorization) to begin participating in Raft. Raft data is transmitted over TLS.
Denial of Service against a node - DoS attacks against a node should not compromise the security stance of the software.
Communication between mesh services - Communications between two mesh-enabled services (natively or by sidecar proxy) should be secure from eavesdropping and provide authentication. This is achieved via mutual TLS.
The following are not part of the threat model for server agents:
Access (read or write) to the Consul data directory - All Consul servers, including non-leaders, persist the full set of Consul state to this directory. The data includes all KV, service registrations, ACL tokens, service mesh CA configuration, and more. Any read or write to this directory allows an attacker to access and tamper with that data.
Access (read or write) to the Consul configuration directory - Consul configuration can enable or disable the ACL system, modify data directory paths, and more. Any read or write of this directory allows an attacker to reconfigure many aspects of Consul. By disabling the ACL system, this may give an attacker access to all Consul data.
Memory access to a running Consul server agent - If an attacker is able to inspect the memory state of a running Consul server agent the confidentiality of almost all Consul data may be compromised. If you're using an external service mesh CA, the root private key material is never available to the Consul process and can be considered safe. Service service mesh TLS certificates should be considered compromised; they are never persisted by server agents but do exist in-memory during at least the duration of a Sign request.
The following are not part of the threat model for client agents:
Access (read or write) to the Consul data directory - Consul clients will use the data directory to cache local state. This includes local services, associated ACL tokens, service mesh TLS certificates, and more. Read or write access to this directory will allow an attacker to access this data. This data is typically a smaller subset of the full data of the cluster.
Access (read or write) to the Consul configuration directory - Consul client configuration files contain the address and port information of services, default ACL tokens for the agent, and more. Access to Consul configuration could enable an attacker to change the port of a service to a malicious port, register new services, and more. Further, some service definitions have ACL tokens attached that could be used cluster-wide to impersonate that service. An attacker cannot change cluster-wide configurations such as disabling the ACL system.
Memory access to a running Consul client agent - The blast radius of this is much smaller than a server agent but the confidentiality of a subset of data can still be compromised. Particularly, any data requested against the agent's API including services, KV, and service mesh information may be compromised. If a particular set of data on the server was never requested by the agent, it never enters the agent's memory since replication only exists between servers. An attacker could also potentially extract ACL tokens used for service registration on this agent, since the tokens must be stored in-memory alongside the registered service.
Network access to a local service mesh proxy or service - Communications between a service and a mesh-aware proxy are generally unencrypted and must happen over a trusted network. This is typically a loopback device. This requires that other processes on the same machine are trusted, or more complex isolation mechanisms are used such as network namespaces. This also requires that external processes cannot communicate to the mesh service or sidecar proxy (except on the inbound port). Therefore, non-native service mesh applications should only bind to non-public addresses.
Improperly Implemented service mesh proxy or service - A service mesh proxy or natively integrated service must correctly serve a valid leaf certificate, verify the inbound TLS client certificate, and call the Consul agent-local authorized endpoint. If any of this isn't performed correctly, the proxy or service may allow unauthenticated or unauthorized connections.
Internal Threats
Operator - A malicious internal Consul operator with a valid mTLS certificate and ACL token may still be a threat to your cluster in certain situations, especially in multi-team deployments. They may accidentally or intentionally abuse access to Consul components which can help be protected against using Namespace, and Sentinel policies.
Application - A malicious internal application, such as a compromised third-party dependency with access to a Consul agent, along with the TLS certificate or ACL token used by the local agent, could effectively do anything the token permits. Consider enabling HTTPS for the local Consul agent API, enforcing full mutual TLS verification, segmenting services using namespaces, as well as configuring OS users, groups, and file permissions to build a defense-in-depth approach.
RPC - Malicious actors with access to a Consul agent RPC endpoint may be able to impersonate Consul server agents if mTLS is not properly configured to verify the client TLS certificate identity. Consul should also have ACLs enabled with a default policy explicitly set to deny to require authorization.
HTTP - Malicious actors with access to a Consul agent HTTP(S) endpoint may be able to impersonate the agent's configured identity, and extract information from Consul when ACLs are disabled.
DNS - Malicious actors with access to a Consul agent DNS endpoint may be able to extract service catalog information.
Gossip - Malicious actors with access to a Consul agent Serf gossip endpoint may be able to impersonate agents within a datacenter. Gossip encryption should be enabled, with a regularly rotated gossip key.
Proxy (xDS) - Malicious actors with access to a Consul agent xDS endpoint may be able to extract Envoy service information. When ACLs and HTTPS are enabled, the gRPC endpoint serving up the xDS service requires (m)TLS and a valid ACL token.
External Threats
Agents - External access to the Consul agent's various network endpoints should be considered including the gossip, HTTP, RPC, and gRPC ports. Furthermore, access through other services like SSH or
exec
functionality in orchestration systems such as Nomad and Kubernetes may expose unencrypted information persisted to disk including TLS certificates or ACL tokens. Access to the Consul agent directory is explicitly outside the scope of Consul's threat model and should only be exposed to authenticated and authorized users.Gateways - Consul supports a variety of gateways to allow traffic in-and-out of the service mesh to support a variety of workloads. When using an internet-exposed gateway, you should be sure to harden your Consul agent and host configurations. In most configurations, ACLS, gossip encryption, and mTLS should be enforced. If an escape hatch override is required, the proxy configuration should be audited to ensure security configurations remain intact, and do not violate Consul's security model.