DC/OS DocumentationOverview
This package provides the DC/OS Calico component to support Calico networking containers and network policies in DC/OS.
DC/OS Calico components
The DC/OS Calico component integrates the Calico networking into DC/OS, by providing the Calico CNI plugin for Mesos Universal Container Runtime and the Calico libnetwork plugin for Docker Engine. The calico control panel also provides configuration for the network policy for DC/OS workloads.
DC/OS Calico services
DC/OS Calico integrates Calico into DC/OS for managing container networking and network security, using these services:
dcos-calico-bird.service: A BGP client that exchanges routing information between hosts for Calico. (source)dcos-calico-confd.service: The confd templating engine monitors etcd datastores and generating and reloading bird configuration dynamically. (source)dcos-calico-felix.service: the control panel for Calico networking to program routes and ACL’s for containers. (source)dcos-calico-libntwork-plugin.service: the network plugin for Docker that provides Calico networking to the Docker Engine. (source)
DC/OS Calico CLI
The DC/OS command line includes a calico plugin that allows running calicoctl commands from outside the cluster. To run any calicoctl command instead, run it as dcos calico for example dcos calico get nodes:
dcos calico get nodes
NAME
172.16.0.23
172.16.2.241
172.16.21.4
172.16.9.234
The DC/OS Calico CLI requires gRPC port to be open and accessible from outside of the cluster on the current leader.
DC/OS network configuration reference
| Parameter | Description |
|---|---|
| calico_network_cidr | Subnet allocated for calico. The subnet specified by calico_network_cidr MUST not overlap with those for VXLAN backends or virtual networks defined for DC/OS virtual networks. [ Default: 172.29.0.0/16 ] |
| calico_vxlan_enabled | Control, whether IP-in-IP or VXLAN mode is used for calico, by default VXLAN is used instead of IP-in-IP. calico_vxlan_enabled set to ‘true’ for the environment that IP in IP is not supported, like Azure. [Default: ‘true’] |
| calico_ipinip_mtu | The MTU to set on the Calico IPIP tunnel device. This configuration works when calico_vxlan_enabled is set to be false. Please refer to the calico documentation for a suitable MTU configuration. [Default: 1480] |
| calico_vxlan_port | The UDP port used for calico VXLAN. This configuration works when calico_vxlan_enabled is set to be true. [Default: 4789] |
| calico_vxlan_vni | The virtual network ID used for calico VXLAN. This configuration works when calico_vxlan_enabled is set to be true. [Default: 4096] |
| calico_vxlan_mtu | The MTU to set on the Calico VXLAN tunnel device. This configuration works when calico_vxlan_enabled is set to be true. Please refer to the calico documentation for a suitable MTU configuration [Default: 1450] |
| calico_veth_mtu | The MTU to set on the veth pair devices, e.g. both the container interface and host-end interface. Please refer to the calico documentation for a suitable MTU configuration [Default: 1500] |
Calico universal container runtime networking
To use Calico networking containers, specify the network name as calico.
The following marathon app definition example will launch a container using the Mesos UCR engine and plug it to the calico network:
{
"id": "/calico-ucr",
"instances": 1,
"container": {
"type": "MESOS",
"volumes": [],
"docker": {
"image": "mesosphere/id-server:2.1.0"
},
"portMappings": []
},
"cpus": 0.1,
"mem": 128,
"requirePorts": false,
"networks": [
{
"mode": "container",
"name": "calico"
}
],
"healthChecks": [],
"fetch": [],
"constraints": []
}
Calico Docker engine networking
Like with the previous example, the following marathon app definition will launch a container using the Docker Engine and plug it to the calico network:
{
"id": "/calico-docker",
"instances": 1,
"container": {
"type": "DOCKER",
"volumes": [],
"docker": {
"image": "mesosphere/id-server:2.1.0"
},
"portMappings": []
},
"cpus": 0.1,
"mem": 128,
"requirePorts": false,
"networks": [
{
"mode": "container",
"name": "calico"
}
],
"healthChecks": [],
"fetch": [],
"constraints": []
}
Administer Calico
Network policies
Network policy provides the ability to control network traffic by an ordered set of rules applied to the endpoints specified by a label selector, please refer to the calico documentation for a detailed explanation of policy rule definitions and label selector syntax.
In DC/OS, Calico network policy is exposed directly to the operators, so that the operator can manage their traffic control according to different scenarios.
limitations on network policy we have in DC/OS:
- Calico network policy is a namespaced resource, but for now, we support only
defaultnamespace in DC/OS, and all the namespaced Calico resources should be defined underdefaultnamespace. - Calico network policy takes effect only on Calico networking containers, which means labels set on non-Calico networking containers like
hostnetwork,dcosandbridgewill not count in Calico network policy. - UCR containers: Labels for network policy MUST be set in
NetworkInfo.Labelsfor Mesos, and for Marathon, they should be innetworks.[].labels, for example:
{
"id": "/client",
"instances": 1,
"container": {
"type": "MESOS",
...
},
...
"networks": [
{
"mode": "container",
"name": "calico",
"labels": {
"role": "client"
}
}
],
...
}
- Docker Containers: Labels for network policy MUST be set in
container.docker.paramatersand prefixed withorg.projectcalico.label, for example:
+```json { “id”: “/client”, “instances”: 1, “container”: { “type”: “Docker”, “docker”: { “parameters”: [ { “key”: “label”, “value”: “org.projectcalico.label.role=client” }, { “key”: “label”, “value”: “org.projectcalico.label.public=yes” } ] }, … }, … }
### Default profile
Calico profile groups endpoints inherit labels defined in the profile, for example, each namespace has one corresponding profile to granting labels to Pods in the namespace. Calico profile supports policy rules for traffic control but is deprecated in favor of the much more flexible NetworkPolicy and GlobalNetworkPolicy resources.
All Calico networking containers will be assigned with a default profile with the same name as CNI network, `calico` by default, and this profile allows all requests. L4LB and L7 proxy requests in which the source IP address is NATed to that of tunnel interfaces generated by Calico are currently not supported. This profile can found in the following YAML definition:
```yaml
apiVersion: projectcalico.org/v3
kind: Profile
metadata:
name: calico
spec:
egress:
- action: Allow
destination: {}
source: {}
ingress:
- action: Allow
destination: {}
source: {}
labelsToApply:
calico: ""
For a more detailed description of the Calico profile, please read the calico documentation.
Network policy examples
In the following business isolation example, we have three application definitions as shown below, and both bookstore-frontend and bookstore-server are labeled with "biz_type": "bookstore", while fruitstore-frontend is labeled with "biz_type": "fruitstore". Here we will create a network policy to deny the requests from fruitstore-frontend to bookstore-server while allow requests from bookstore-frontend to bookstore-server.
+----------------------+ +------------------------+
| | | |
| bookstore-frontend | | fruitstore-frontend |
| | | |
+-----------------+----+ +----+-------------------+
| |
| |
| x
| |
+----v----------------v--+
| |
| bookstore-server |
| |
+------------------------+
5.3.1. Launch Marathon applications
The Marathon application definition of bookstore-frontend with policy label "biz_type": "bookstore":
{
"id": "/bookstore-frontend",
"instances": 1,
"container": {
"type": "MESOS",
"volumes": [],
"docker": {
"image": "mesosphere/id-server:2.1.0"
},
"portMappings": []
},
"cpus": 0.1,
"mem": 128,
"requirePorts": false,
"networks": [
{
"mode": "container",
"name": "calico",
"labels": {
"biz_type": "bookstore"
}
}
],
"healthChecks": [],
"fetch": [],
"constraints": []
}
The Marathon application definition of bookstore-server with policy label "biz_type": "bookstore" and "role": "server", available on port 80:
{
"id": "/bookstore-server",
"instances": 1,
"container": {
"type": "MESOS",
"volumes": [],
"docker": {
"image": "mesosphere/id-server:2.1.0"
},
"portMappings": []
},
"cpus": 0.1,
"mem": 128,
"requirePorts": false,
"networks": [
{
"mode": "container",
"name": "calico",
"labels": {
"biz_type": "bookstore",
"role": "server"
}
}
],
"healthChecks": [],
"fetch": [],
"constraints": []
}
The Marathon application definition of fruitstore-frontend with policy label "biz_type": "fruitstore":
{
"id": "/fruitstore-frontend",
"instances": 1,
"container": {
"type": "MESOS",
"volumes": [],
"docker": {
"image": "mesosphere/id-server:2.1.0"
},
"portMappings": []
},
"cpus": 0.1,
"mem": 128,
"requirePorts": false,
"networks": [
{
"mode": "container",
"name": "calico",
"labels": {
"biz_type": "fruitstore"
}
}
],
"healthChecks": [],
"fetch": [],
"constraints": []
}
Lauch the above three Marathon applications by executing dcos marathon app add ${app_definition_yaml_file}, and we will then obtain three running Marathon applications as show below:
dcos task list
NAME HOST USER STATE ID AGENT ID REGION ZONE
fruitstore-frontend 172.16.2.233 root TASK_RUNNING fruitstore-frontend.instance-8a3ed6db-2a47-11ea-91b3-66db602e14f5._app.1 0a1399a2-fe1f-4613-a618-f45159e12f2a-S0 N/A N/A
bookstore-server 172.16.29.45 root TASK_RUNNING bookstore-server.instance-825bcbda-2a47-11ea-91b3-66db602e14f5._app.1 0a1399a2-fe1f-4613-a618-f45159e12f2a-S1 N/A N/A
bookstore-frontend 172.16.2.233 root TASK_RUNNING bookstore-frontend.instance-79853919-2a47-11ea-91b3-66db602e14f5._app.1 0a1399a2-fe1f-4613-a618-f45159e12f2a-S0 N/A N/A
Frontends and server connectivity test
Before applying network policy, the requests from bookstore-frontend and fruitstore-frontend to bookstore-server are successful, here we expect the FQDN bookstore-server.marathon.containerip.dcos.thisdcos.directory to return the bookstore-server container IP address:
dcos task exec fruitstore-frontend wget -qO- bookstore-server.marathon.containerip.dcos.thisdcos.directory:80/id
hubfeu2yculh%
dcos task exec bookstore-frontend wget -qO- bookstore-server.marathon.containerip.dcos.thisdcos.directory:80/id
hubfeu2yculh%
Apply network policy
This network policy takes effect on bookstore-server and allows requests from applications with label biz_type set as bookstore while rejects those from applications with label biz_type set as fruitstore:
apiVersion: projectcalico.org/v3
kind: NetworkPolicy
metadata:
name: allow-bookstore-cliient-to-server
spec:
selector: biz_type == 'bookstore' && role == 'server'
types:
- Ingress
ingress:
- action: Allow
protocol: TCP
source:
selector: biz_type == 'bookstore'
destination:
ports:
- 80
- action: Deny
protocol: TCP
source:
selector: biz_type == 'fruitstore'
destination:
ports:
- 80
Temporarily, we can log into a DC/OS node, and apply the network policy by executing dcos calico apply -f ${network_policy_yaml_file}.
Request from bookstore-frontend is successful as expected:
dcos task exec bookstore-frontend wget -qO- bookstore-server.marathon.containerip.dcos.thisdcos.directory:80/id
hubfeu2yculh%
Request from fruitstore-frontend is timed out for packets are dropped.
dcos task exec fruitstore-frontend wget -qO- --timeout=5 bookstore-server.marathon.containerip.dcos.thisdcos.directory:80/id
wget: can't connect to remote host (192.168.219.133): Connection timed out
Adding network profiles
In most of the use cases a single calico profile is enough. However if for any reason more networks needs to be created, you should be aware of some corner cases.
⚠️ NOTE: The
calico-libnetwork-plugin(the network interface to Docker Runtime) implicitly links the IP Pool to the calico profile associated with the respective calico docker network.
That said, to add a network profile, you should:
- Create a new IP pool. For example:
apiVersion: projectcalico.org/v3
kind: IPPool
metadata:
name: <network-name>
spec:
cidr: 10.1.0.0/16
natOutgoing: true
disabled: false
Save the above yaml to ip.yml then run:
dcos calico create -f ip.yml
- Create a new calico profile. For example:
apiVersion: projectcalico.org/v3
kind: Profile
metadata:
name: <profile-name>
spec:
egress:
- action: Allow
destination: {}
source: {}
ingress:
- action: Allow
destination: {}
source: {}
labelsToApply:
calico: ""
Save the above yaml to profile.yml then run:
dcos calico create -f profile.yml
- On every agent, create a new docker network that will use the new profile. You can use the following command, making sure the subnet matches the cidr from the pool:
docker network create \
--opt org.projectcalico.profile=<profile-name> \
--driver calico \
--ipam-driver calico-ipam \
--subnet=10.1.0.0/16 \
<network-name>
Migrate applications from DC/OS overlay to Calico
Automatic Migration for all services existing within a DC/OS cluster is impossible. Services can be launched by a variety of Apache Mesos frameworks ranging from production-proven platform Marathon to services built on top of [dcos-common](https://github.com/mesosphere/dcos-commons. This includes existing, stateful services such as Cassandra and Spark, or services being hosted from your environment.
Marathon application (aka DC/OS services)
There are at least two ways to effect a change for the Marathon application:
- DC/OS CLI
Update the application definition to replace the network name
dcoswithcalicodcos app update calico_network_app.json
for this method, the corresponding file, calico_network_app.json contains the definition of a Calico network application that differs from a DC/OS network application as follows:
{
"networks": [
{
"mode": "container",
- "name": "dcos"
+ "name": "calico"
}
]
}
- DC/OS GUI
Navigate to the networking tab for services, and change the network type from Virtual Network: dcos to Virtual Network: calico.
DC/OS services built on top of dcos-common
Normally, there are two components in DC/OS services:
- Scheduler - a Marathon application executing a plan to launch a Pod
- Pods - worker applications performing the service’s responsibilities.
As the definition of the scheduler and pods are defined as release packages, and to make a permanent change in case the scheduler and Pods are using a virtual network, we have to generate new releases of DC/OS services after executing the following changes:
-
For Schedulers The Marathon application definition of a scheduler is defined as a template, marathon.json.mustache, inside the package definition, and is filled out by the operators according to the variables defined in
config.json. The operator is expected to make sureVIRTUAL_NETWORK_NAMEto becalicowhen the virtual network is enabled. -
For Pods
dcos-commonallows pods to join virtual networks, with thedcosvirtual network available by default. Migrating the application fromdcostocalicorequires the change as follows:
pods:
pod-on-virtual-network:
count:
networks:
- dcos:
+ calico:
tasks:
...
pod-on-host:
count:
tasks:
...
Troubleshoot
Diagnostic info including Calico resources, components logs, and BGP peer status are collected in DC/OS node diagnostic bundle to debug Calico networking issues, please execute dcos node diagnostic create to create a diagnostic bundle, and download the diagnostic bundle by executing dcos node diagnostic download <diagnostic-bundle-name>.