Autodiscover
editAutodiscover
editWhen you run applications on containers, they become moving targets to the monitoring system. Autodiscover allows you to track them and adapt settings as changes happen. By defining configuration templates, the autodiscover subsystem can monitor services as they start running.
You define autodiscover settings in the heartbeat.autodiscover
section of the heartbeat.yml
config file. To enable autodiscover, you specify a list of providers.
Providers
editAutodiscover providers work by watching for events on the system and translating those events into internal autodiscover events with a common format. When you configure the provider, you can optionally use fields from the autodiscover event to set conditions that, when met, launch specific configurations.
On start, Heartbeat will scan existing containers and launch the proper configs for them. Then it will watch for new start/stop events. This ensures you don’t need to worry about state, but only define your desired configs.
Docker
editThe Docker autodiscover provider watches for Docker containers to start and stop.
It has the following settings:
-
host
-
(Optional) Docker socket (UNIX or TCP socket). It uses
unix:///var/run/docker.sock
by default. -
ssl
- (Optional) SSL configuration to use when connecting to the Docker socket.
-
cleanup_timeout
- (Optional) Specify the time of inactivity before stopping the running configuration for a container, disabled by default.
-
labels.dedot
-
(Optional) Default to be false. If set to true, replace dots in
labels with
_
.
These are the fields available within config templating. The docker.*
fields will be available on each emitted event.
event:
- host
- port
- docker.container.id
- docker.container.image
- docker.container.name
- docker.container.labels
For example:
{ "host": "10.4.15.9", "port": 6379, "docker": { "container": { "id": "382184ecdb385cfd5d1f1a65f78911054c8511ae009635300ac28b4fc357ce51" "name": "redis", "image": "redis:3.2.11", "labels": { "io.kubernetes.pod.namespace": "default" ... } } } }
You can define a set of configuration templates to be applied when the condition matches an event. Templates define a condition to match on autodiscover events, together with the list of configurations to launch when this condition happens.
Conditions match events from the provider. Providers use the same format for Conditions that processors use.
Configuration templates can contain variables from the autodiscover event. They can be accessed under the data
namespace.
For example, with the example event, "${data.port}
" resolves to 6379
.
Heartbeat supports templates for modules:
heartbeat.autodiscover: providers: - type: docker templates: - condition: contains: docker.container.image: redis config: - type: tcp hosts: ["${data.host}:${data.port}"] schedule: "@every 1s" timeout: 1s
This configuration launches a redis
monitor for all containers running an image with redis
in the name.
Kubernetes
editThe Kubernetes autodiscover provider watches for Kubernetes nodes, pods, services to start, update, and stop.
The kubernetes
autodiscover provider has the following configuration settings:
-
node
- (Optional) Specify the node to scope heartbeat to in case it cannot be accurately detected, as when running heartbeat in host network mode.
-
namespace
- (Optional) Select the namespace from which to collect the metadata. If it is not set, the processor collects metadata from all namespaces. It is unset by default. The namespace configuration only applies to kubernetes resources that are namespace scoped.
-
cleanup_timeout
- (Optional) Specify the time of inactivity before stopping the running configuration for a container, disabled by default.
-
kube_config
- (Optional) Use given config file as configuration for Kubernetes client. If kube_config is not set, KUBECONFIG environment variable will be checked and if not present it will fall back to InCluster.
-
kube_client_options
- (Optional) Additional options can be configured for Kubernetes client. Currently client QPS and burst are supported, if not set Kubernetes client’s default QPS and burst will be used. Example:
kube_client_options: qps: 5 burst: 10
-
resource
-
(Optional) Select the resource to do discovery on. Currently supported
Kubernetes resources are
pod
,service
andnode
. If not configuredresource
defaults topod
. -
scope
-
(Optional) Specify at what level autodiscover needs to be done at.
scope
can either takenode
orcluster
as values.node
scope allows discovery of resources in the specified node.cluster
scope allows cluster wide discovery. Onlypod
andnode
resources can be discovered at node scope. -
add_resource_metadata
-
(Optional) Specify filters and configration for the extra metadata, that will be added to the event. Configuration parameters:
-
node
ornamespace
: Specify labels and annotations filters for the extra metadata coming from node and namespace. By default all labels are included while annotations are not. To change default behaviourinclude_labels
,exclude_labels
andinclude_annotations
can be defined. Those settings are useful when storing labels and annotations that require special handling to avoid overloading the storage output. Note: wildcards are not supported for those settings. The enrichment ofnode
ornamespace
metadata can be individually disabled by settingenabled: false
. -
deployment
: If resource ispod
and it is created from adeployment
, by default the deployment name is added, this can be disabled by settingdeployment: false
. -
cronjob
: If resource ispod
and it is created from acronjob
, by default the cronjob name is added, this can be disabled by settingcronjob: false
.Example:
-
add_resource_metadata: namespace: include_labels: ["namespacelabel1"] node: include_labels: ["nodelabel2"] include_annotations: ["nodeannotation1"] deployment: false cronjob: false
-
unique
-
(Optional) Defaults to
false
. Marking an autodiscover provider as unique results into making the provider to enable the provided templates only when it will gain the leader lease. This setting can only be combined withcluster
scope. Whenunique
is enabled enabled,resource
andadd_resource_metadata
settings are not taken into account. -
leader_lease
-
(Optional) Defaults to
heartbeat-cluster-leader
. This will be name of the lock lease. One can monitor the status of the lease withkubectl describe lease beats-cluster-leader
. Different Beats that refer to the same leader lease will be competitors in holding the lease and only one will be elected as leader each time.
The configuration of templates and conditions is similar to that of the Docker provider. Configuration templates can contain variables from the autodiscover event. They can be accessed under data namespace.
These are the fields available within config templating. The kubernetes.*
fields will be available on each emitted event.
Generic fields:
edit- host
- port (if exposed)
- kubernetes.labels
- kubernetes.annotations
Pod specific:
edit- kubernetes.container.id
- kubernetes.container.image
- kubernetes.container.name
- kubernetes.namespace
- kubernetes.node.name
- kubernetes.pod.name
- kubernetes.pod.uid
Node specific:
edit- kubernetes.node.name
- kubernetes.node.uid
Service specific:
edit- kubernetes.namespace
- kubernetes.service.name
- kubernetes.service.uid
- kubernetes.annotations
If the include_annotations
config is added to the provider config, then the list of annotations present in the config
are added to the event.
If the include_labels
config is added to the provider config, then the list of labels present in the config
will be added to the event.
If the exclude_labels
config is added to the provider config, then the list of labels present in the config
will be excluded from the event.
if the labels.dedot
config is set to be true
in the provider config, then .
in labels will be replaced with _
.
By default it is true
.
if the annotations.dedot
config is set to be true
in the provider config, then .
in annotations will be replaced
with _
. By default it is true
.
Starting from 8.6 release kubernetes.labels.*
used in config templating are not dedoted regardless of labels.dedot
value.
This config parameter only affects the fields added in the final Elasticsearch document. For example, for a pod with label app.kubernetes.io/name=ingress-nginx
the matching condition should be condition.equals:
kubernetes.labels.app.kubernetes.io/name: "ingress-nginx"
. If labels.dedot
is set to true
(default value)
the label will be stored in Elasticsearch as kubernetes.labels.app_kubernetes_io/name
. The same applies for kubernetes annotations.
For example:
{ "host": "172.17.0.21", "port": 9090, "kubernetes": { "container": { "id": "bb3a50625c01b16a88aa224779c39262a9ad14264c3034669a50cd9a90af1527", "image": "prom/prometheus", "name": "prometheus" }, "labels": { "project": "prometheus", ... }, "namespace": "default", "node": { "name": "minikube" }, "pod": { "name": "prometheus-2657348378-k1pnh" } }, }
Heartbeat supports templates for modules:
heartbeat.autodiscover: providers: - type: kubernetes include_annotations: ["prometheus.io.scrape"] templates: - condition: contains: kubernetes.annotations.prometheus.io/scrape: "true" config: - type: http hosts: ["${data.host}:${data.port}"] schedule: "@every 1s" timeout: 1s
This configuration launches an http
module for all containers of pods annotated with prometheus.io/scrape=true
.
Amazon ELBs (Deprecated)
editNote: This provider is now deprecated and will be removed in a future release.
The Amazon ELB autodiscover provider discovers ELBs and their listeners. This is useful when you don’t want to connect directly to a service, but rather to the ELB fronting a pool of services.
This provider will yield one config block per ELB Listener. So, if you have one ELB exposing both ports 80 and 443, it will generate two configs, one for each port. Keep in mind that the beat will de-duplicate configs. So, if the generated configs are the same only one will actually run.
This provider will load AWS credentials using the standard AWS environment variables and shared credentials files see Best Practices for Managing AWS Access Keys for more information. If you do not wish to use these, you may explicitly set the access_key_id
and secret_access_key
variables.
These are the available fields during within config templating. The aws.elb.*
fields will be available on each emitted event.
- host
- port
- cloud.availability_zone
- cloud.provider
- cloud.region
- aws.elb.listener_arn
- aws.elb.load_balancer_arn
- aws.elb.protocol
- aws.elb.type
- aws.elb.scheme
- aws.elb.availability_zones
- aws.elb.created
- aws.elb.state.code
- aws.elb.state.reason
- aws.elb.ip_address_type
- aws.elb.security_groups
- aws.elb.vpc_id
- aws.elb.ssl_policy
Heartbeat supports templates for modules:
heartbeat.autodiscover: providers: - type: aws_elb period: 1m regions: ["us-east-1", "us-east-2"] access_key_id: my-access-key secret_access_key: my-secret-access-key templates: - condition: equals.port: 8080 config: - type: tcp hosts: ["${data.host}:${data.port}"] schedule: "@every 5s" timeout: 1s
This configuration launches a tcp
monitor for all ELBs that have a declared port.
This autodiscover provider takes our standard AWS credentials options.
AWS Credentials Configuration
editTo configure AWS credentials, either put the credentials into the Heartbeat configuration, or use a shared credentials file, as shown in the following examples.
Configuration parameters
edit- access_key_id: first part of access key.
- secret_access_key: second part of access key.
- session_token: required when using temporary security credentials.
- credential_profile_name: profile name in shared credentials file.
- shared_credential_file: directory of the shared credentials file.
- role_arn: AWS IAM Role to assume.
- external_id: external ID to use when assuming a role in another account, see the AWS documentation for use of external IDs.
-
proxy_url: URL of the proxy to use to connect to AWS web services. The syntax is
http(s)://<IP/Hostname>:<port>
-
fips_enabled: Enabling this option instructs Heartbeat to use the FIPS endpoint of a service. All services used by Heartbeat are FIPS compatible except for
tagging
but only certain regions are FIPS compatible. See https://aws.amazon.com/compliance/fips/ or the appropriate service page, https://docs.aws.amazon.com/general/latest/gr/aws-service-information.html, for a full list of FIPS endpoints and regions. - ssl: This specifies SSL/TLS configuration. If the ssl section is missing, the host’s CAs are used for HTTPS connections. See SSL for more information.
- default_region: Default region to query if no other region is set. Most AWS services offer a regional endpoint that can be used to make requests. Some services, such as IAM, do not support regions. If a region is not provided by any other way (environment variable, credential or instance profile), the value set here will be used.
Supported Formats
editThe examples in this section refer to Metricbeat, but the credential options for authentication with AWS are the same no matter which Beat is being used.
-
Use
access_key_id
,secret_access_key
, and/orsession_token
Users can either put the credentials into the Metricbeat module configuration or use
environment variable AWS_ACCESS_KEY_ID
, AWS_SECRET_ACCESS_KEY
and/or
AWS_SESSION_TOKEN
instead.
If running on Docker, these environment variables should be added as a part of the docker command. For example, with Metricbeat:
$ docker run -e AWS_ACCESS_KEY_ID=abcd -e AWS_SECRET_ACCESS_KEY=abcd -d --name=metricbeat --user=root --volume="$(pwd)/metricbeat.aws.yml:/usr/share/metricbeat/metricbeat.yml:ro" docker.elastic.co/beats/metricbeat:7.11.1 metricbeat -e -E cloud.auth=elastic:1234 -E cloud.id=test-aws:1234
Sample metricbeat.aws.yml
looks like:
metricbeat.modules: - module: aws period: 5m access_key_id: ${AWS_ACCESS_KEY_ID} secret_access_key: ${AWS_SECRET_ACCESS_KEY} session_token: ${AWS_SESSION_TOKEN} metricsets: - ec2
Environment variables can also be added through a file. For example:
$ cat env.list AWS_ACCESS_KEY_ID=abcd AWS_SECRET_ACCESS_KEY=abcd $ docker run --env-file env.list -d --name=metricbeat --user=root --volume="$(pwd)/metricbeat.aws.yml:/usr/share/metricbeat/metricbeat.yml:ro" docker.elastic.co/beats/metricbeat:7.11.1 metricbeat -e -E cloud.auth=elastic:1234 -E cloud.id=test-aws:1234
-
Use
credential_profile_name
and/orshared_credential_file
If access_key_id
, secret_access_key
and role_arn
are all not given, then
heartbeat will check for credential_profile_name
. If you use different credentials for
different tools or applications, you can use profiles to configure multiple
access keys in the same configuration file. If there is no credential_profile_name
given, the default profile will be used.
shared_credential_file
is optional to specify the directory of your shared
credentials file. If it’s empty, the default directory will be used.
In Windows, shared credentials file is at C:\Users\<yourUserName>\.aws\credentials
.
For Linux, macOS or Unix, the file is located at ~/.aws/credentials
. When running as a service,
the home path depends on the user that manages the service, so the shared_credential_file
parameter can be used to avoid ambiguity. Please see
Create Shared Credentials File
for more details.
-
Use
role_arn
role_arn
is used to specify which AWS IAM role to assume for generating
temporary credentials. If role_arn
is given, heartbeat will check if
access keys are given. If not, heartbeat will check for credential profile
name. If neither is given, default credential profile will be used. Please make
sure credentials are given under either a credential profile or access keys.
If running on Docker, the credential file needs to be provided via a volume mount. For example, with Metricbeat:
docker run -d --name=metricbeat --user=root --volume="$(pwd)/metricbeat.aws.yml:/usr/share/metricbeat/metricbeat.yml:ro" --volume="/Users/foo/.aws/credentials:/usr/share/metricbeat/credentials:ro" docker.elastic.co/beats/metricbeat:7.11.1 metricbeat -e -E cloud.auth=elastic:1234 -E cloud.id=test-aws:1234
Sample metricbeat.aws.yml
looks like:
metricbeat.modules: - module: aws period: 5m credential_profile_name: elastic-beats shared_credential_file: /usr/share/metricbeat/credentials metricsets: - ec2
heartbeat.autodiscover: providers: - type: aws_elb period: 1m regions: ["us-east-1", "us-east-2"] access_key_id: '<access_key_id>' secret_access_key: '<secret_access_key>' session_token: '<session_token>' templates: - type: tcp hosts: ["${data.host}:${data.port}"] schedule: "@every 5s" timeout: 1s
or
heartbeat.autodiscover: providers: - type: aws_elb period: 1m regions: ["us-east-1", "us-east-2"] access_key_id: '${AWS_ACCESS_KEY_ID:""}' secret_access_key: '${AWS_SECRET_ACCESS_KEY:""}' session_token: '${AWS_SESSION_TOKEN:""}' templates: - type: tcp hosts: ["${data.host}:${data.port}"] schedule: "@every 5s" timeout: 1s
- Use shared AWS credentials file
heartbeat.autodiscover: providers: - type: aws_elb period: 1m regions: ["us-east-1", "us-east-2"] credential_profile_name: test-hb templates: - type: tcp hosts: ["${data.host}:${data.port}"] schedule: "@every 5s" timeout: 1s
AWS Credentials Types
editThere are two different types of AWS credentials can be used: access keys and temporary security credentials.
- Access keys
AWS_ACCESS_KEY_ID
and AWS_SECRET_ACCESS_KEY
are the two parts of access keys.
They are long-term credentials for an IAM user or the AWS account root user.
Please see
AWS Access Keys
and Secret Access Keys
for more details.
- IAM role ARN
An IAM role is an IAM identity that you can create in your account that has specific permissions that determine what the identity can and cannot do in AWS. A role does not have standard long-term credentials such as a password or access keys associated with it. Instead, when you assume a role, it provides you with temporary security credentials for your role session. IAM role Amazon Resource Name (ARN) can be used to specify which AWS IAM role to assume to generate temporary credentials. Please see AssumeRole API documentation for more details.
Here are the steps to set up IAM role using AWS CLI for Metricbeat. Please replace
123456789012
with your own account ID.
Step 1. Create example-policy.json
file to include all permissions:
{ "Version": "2012-10-17", "Statement": [ { "Sid": "VisualEditor0", "Effect": "Allow", "Action": [ "s3:GetObject", "sqs:ReceiveMessage" ], "Resource": "*" }, { "Sid": "VisualEditor1", "Effect": "Allow", "Action": "sqs:ChangeMessageVisibility", "Resource": "arn:aws:sqs:us-east-1:123456789012:test-fb-ks" }, { "Sid": "VisualEditor2", "Effect": "Allow", "Action": "sqs:DeleteMessage", "Resource": "arn:aws:sqs:us-east-1:123456789012:test-fb-ks" }, { "Sid": "VisualEditor3", "Effect": "Allow", "Action": [ "sts:AssumeRole", "sqs:ListQueues", "tag:GetResources", "ec2:DescribeInstances", "cloudwatch:GetMetricData", "ec2:DescribeRegions", "iam:ListAccountAliases", "sts:GetCallerIdentity", "cloudwatch:ListMetrics" ], "Resource": "*" } ] }
Step 2. Create IAM policy using the aws iam create-policy
command:
$ aws iam create-policy --policy-name example-policy --policy-document file://example-policy.json
Step 3. Create the JSON file example-role-trust-policy.json
that defines the trust relationship of the IAM role
{ "Version": "2012-10-17", "Statement": { "Effect": "Allow", "Principal": { "AWS": "arn:aws:iam::123456789012:root" }, "Action": "sts:AssumeRole" } }
Step 4. Create the IAM role and attach the policy:
$ aws iam create-role --role-name example-role --assume-role-policy-document file://example-role-trust-policy.json $ aws iam attach-role-policy --role-name example-role --policy-arn "arn:aws:iam::123456789012:policy/example-policy"
After these steps are done, IAM role ARN can be used for authentication in Metricbeat
aws
module.
- Temporary security credentials
Temporary security credentials has a limited lifetime and consists of an
access key ID, a secret access key, and a security token which typically returned
from GetSessionToken
. MFA-enabled IAM users would need to submit an MFA code
while calling GetSessionToken
. Please see
Temporary Security Credentials
for more details.
sts get-session-token
AWS CLI can be used to generate temporary credentials. For example. with MFA-enabled:
aws> sts get-session-token --serial-number arn:aws:iam::1234:mfa/your-email@example.com --token-code 456789 --duration-seconds 129600
Because temporary security credentials are short term, after they expire, the user needs to generate new ones and modify the aws.yml config file with the new credentials. Unless live reloading feature is enabled for Metricbeat, the user needs to manually restart Metricbeat after updating the config file in order to continue collecting Cloudwatch metrics. This will cause data loss if the config file is not updated with new credentials before the old ones expire. For Metricbeat, we recommend users to use access keys in config file to enable aws module making AWS api calls without have to generate new temporary credentials and update the config frequently.
IAM policy is an entity that defines permissions to an object within your AWS environment. Specific permissions needs to be added into the IAM user’s policy to authorize Metricbeat to collect AWS monitoring metrics. Please see documentation under each metricset for required permissions.