20 KiB
| title | description | keywords | |
|---|---|---|---|
| service create | The service create command description and usage |
|
service create
Usage: docker service create [OPTIONS] IMAGE [COMMAND] [ARG...]
Create a new service
Options:
--constraint value Placement constraints (default [])
--container-label value Service container labels (default [])
--endpoint-mode string Endpoint mode (vip or dnsrr)
-e, --env value Set environment variables (default [])
--env-file value Read in a file of environment variables (default [])
--group value Set one or more supplementary user groups for the container (default [])
--health-cmd string Command to run to check health
--health-interval duration Time between running the check
--health-retries int Consecutive failures needed to report unhealthy
--health-timeout duration Maximum time to allow one check to run
--help Print usage
-l, --label value Service labels (default [])
--limit-cpu value Limit CPUs (default 0.000)
--limit-memory value Limit Memory (default 0 B)
--log-driver string Logging driver for service
--log-opt value Logging driver options (default [])
--mode string Service mode (replicated or global) (default "replicated")
--mount value Attach a mount to the service
--name string Service name
--network value Network attachments (default [])
--no-healthcheck Disable any container-specified HEALTHCHECK
-p, --publish value Publish a port as a node port (default [])
--replicas value Number of tasks (default none)
--reserve-cpu value Reserve CPUs (default 0.000)
--reserve-memory value Reserve Memory (default 0 B)
--restart-condition string Restart when condition is met (none, on-failure, or any)
--restart-delay value Delay between restart attempts (default none)
--restart-max-attempts value Maximum number of restarts before giving up (default none)
--restart-window value Window used to evaluate the restart policy (default none)
--stop-grace-period value Time to wait before force killing a container (default none)
--update-delay duration Delay between updates
--update-failure-action string Action on update failure (pause|continue) (default "pause")
--update-max-failure-ratio value Failure rate to tolerate during an update
--update-monitor duration Duration after each task update to monitor for failure (default 0s)
--update-parallelism uint Maximum number of tasks updated simultaneously (0 to update all at once) (default 1)
-u, --user string Username or UID (format: <name|uid>[:<group|gid>])
--with-registry-auth Send registry authentication details to Swarm agents
-w, --workdir string Working directory inside the container
Creates a service as described by the specified parameters. You must run this command on a manager node.
Examples
Create a service
$ docker service create --name redis redis:3.0.6
dmu1ept4cxcfe8k8lhtux3ro3
$ docker service ls
ID NAME REPLICAS IMAGE COMMAND
dmu1ept4cxcf redis 1/1 redis:3.0.6
Create a service with 5 replica tasks (--replicas)
Use the --replicas flag to set the number of replica tasks for a replicated
service. The following command creates a redis service with 5 replica tasks:
$ docker service create --name redis --replicas=5 redis:3.0.6
4cdgfyky7ozwh3htjfw0d12qv
The above command sets the desired number of tasks for the service. Even
though the command returns immediately, actual scaling of the service may take
some time. The REPLICAS column shows both the actual and desired number
of replica tasks for the service.
In the following example the desired state is 5 replicas, but the current
number of RUNNING tasks is 3:
$ docker service ls
ID NAME REPLICAS IMAGE COMMAND
4cdgfyky7ozw redis 3/5 redis:3.0.7
Once all the tasks are created and RUNNING, the actual number of tasks is
equal to the desired number:
$ docker service ls
ID NAME REPLICAS IMAGE COMMAND
4cdgfyky7ozw redis 5/5 redis:3.0.7
Create a service with a rolling update policy
$ docker service create \
--replicas 10 \
--name redis \
--update-delay 10s \
--update-parallelism 2 \
redis:3.0.6
When you run a service update, the scheduler updates a
maximum of 2 tasks at a time, with 10s between updates. For more information,
refer to the rolling updates
tutorial.
Set environment variables (-e, --env)
This sets environmental variables for all tasks in a service. For example:
$ docker service create --name redis_2 --replicas 5 --env MYVAR=foo redis:3.0.6
Set metadata on a service (-l, --label)
A label is a key=value pair that applies metadata to a service. To label a
service with two labels:
$ docker service create \
--name redis_2 \
--label com.example.foo="bar"
--label bar=baz \
redis:3.0.6
For more information about labels, refer to apply custom metadata.
Add bind-mounts or volumes
Docker supports two different kinds of mounts, which allow containers to read to or write from files or directories on other containers or the host operating system. These types are data volumes (often referred to simply as volumes) and bind-mounts.
A bind-mount makes a file or directory on the host available to the
container it is mounted within. A bind-mount may be either read-only or
read-write. For example, a container might share its host's DNS information by
means of a bind-mount of the host's /etc/resolv.conf or a container might
write logs to its host's /var/log/myContainerLogs directory. If you use
bind-mounts and your host and containers have different notions of permissions,
access controls, or other such details, you will run into portability issues.
A named volume is a mechanism for decoupling persistent data needed by your container from the image used to create the container and from the host machine. Named volumes are created and managed by Docker, and a named volume persists even when no container is currently using it. Data in named volumes can be shared between a container and the host machine, as well as between multiple containers. Docker uses a volume driver to create, manage, and mount volumes. You can back up or restore volumes using Docker commands.
Consider a situation where your image starts a lightweight web server. You could use that image as a base image, copy in your website's HTML files, and package that into another image. Each time your website changed, you'd need to update the new image and redeploy all of the containers serving your website. A better solution is to store the website in a named volume which is attached to each of your web server containers when they start. To update the website, you just update the named volume.
For more information about named volumes, see Data Volumes.
The following table describes options which apply to both bind-mounts and named volumes in a service:
| Option | Required | Description |
|---|---|---|
| type | The type of mount, can be either volume, or bind. Defaults to volume if no type is specified.
|
|
| src or source | for type=bind only |
|
| dst or destination or target | yes | Mount path inside the container, for example /some/path/in/container/. If the path does not exist in the container's filesystem, the Engine creates a directory at the specified location before mounting the volume or bind-mount. |
| readonly or ro | The Engine mounts binds and volumes read-write unless readonly option is given when mounting the bind or volume.
|
Bind Propagation
Bind propagation refers to whether or not mounts created within a given
bind-mount or named volume can be propagated to replicas of that mount. Consider
a mount point /mnt, which is also mounted on /tmp. The propation settings
control whether a mount on /tmp/a would also be available on /mnt/a. Each
propagation setting has a recursive counterpoint. In the case of recursion,
consider that /tmp/a is also mounted as /foo. The propagation settings
control whether /mnt/a and/or /tmp/a would exist.
The bind-propagation option defaults to rprivate for both bind-mounts and
volume mounts, and is only configurable for bind-mounts. In other words, named
volumes do not support bind propagation.
shared: Sub-mounts of the original mount are exposed to replica mounts, and sub-mounts of replica mounts are also propagated to the original mount.slave: similar to a shared mount, but only in one direction. If the original mount exposes a sub-mount, the replica mount can see it. However, if the replica mount exposes a sub-mount, the original mount cannot see it.private: The mount is private. Sub-mounts within it are not exposed to replica mounts, and sub-mounts of replica mounts are not exposed to the original mount.rshared: The same as shared, but the propagation also extends to and from mount points nested within any of the original or replica mount points.rslave: The same asslave, but the propagation also extends to and from mount points nested within any of the original or replica mount points.rprivate: The default. The same asprivate, meaning that no mount points anywhere within the original or replica mount points propagate in either direction.
For more information about bind propagation, see the Linux kernel documentation for shared subtree.
Options for Named Volumes
The following options can only be used for named volumes (type=volume);
| Option | Description |
|---|---|
| volume-driver | Name of the volume-driver plugin to use for the volume. Defaults to "local", to use the local volume driver to create the volume if the volume does not exist. |
| volume-label | One or more custom metadata ("labels") to apply to the volume upon creation. For example, volume-label=mylabel=hello-world,my-other-label=hello-mars. For more information about labels, refer to apply custom metadata. |
| volume-nocopy | By default, if you attach an empty volume to a container, and files or directories already existed at the mount-path in the container (dst), the Engine copies those files and directories into the volume, allowing the host to access them. Set volume-nocopy to disables copying files from the container's filesystem to the volume and mount the empty volume.A value is optional:
|
| volume-opt | Options specific to a given volume driver, which will be passed to the driver when creating the volume. Options are provided as a comma-separated list of key/value pairs, for example, volume-opt=some-option=some-value,some-other-option=some-other-value. For available options for a given driver, refer to that driver's documentation. |
Differences between "--mount" and "--volume"
The --mount flag supports most options that are supported by the -v
or --volume flag for docker run, with some important exceptions:
-
The
--mountflag allows you to specify a volume driver and volume driver options per volume, without creating the volumes in advance. In contrast,docker runallows you to specify a single volume driver which is shared by all volumes, using the--volume-driverflag. -
The
--mountflag allows you to specify custom metadata ("labels") for a volume, before the volume is created. -
When you use
--mountwithtype=bind, the host-path must refer to an existing path on the host. The path will not be created for you and the service will fail with an error if the path does not exist. -
The
--mountflag does not allow you to relabel a volume withZorzflags, which are used forselinuxlabeling.
Create a service using a named volume
The following example creates a service that uses a named volume:
$ docker service create \
--name my-service \
--replicas 3 \
--mount type=volume,source=my-volume,destination=/path/in/container,volume-label="color=red",volume-label="shape=round" \
nginx:alpine
For each replica of the service, the engine requests a volume named "my-volume" from the default ("local") volume driver where the task is deployed. If the volume does not exist, the engine creates a new volume and applies the "color" and "shape" labels.
When the task is started, the volume is mounted on /path/in/container/ inside
the container.
Be aware that the default ("local") volume is a locally scoped volume driver. This means that depending on where a task is deployed, either that task gets a new volume named "my-volume", or shares the same "my-volume" with other tasks of the same service. Multiple containers writing to a single shared volume can cause data corruption if the software running inside the container is not designed to handle concurrent processes writing to the same location. Also take into account that containers can be re-scheduled by the Swarm orchestrator and be deployed on a different node.
Create a service that uses an anonymous volume
The following command creates a service with three replicas with an anonymous
volume on /path/in/container:
$ docker service create \
--name my-service \
--replicas 3 \
--mount type=volume,destination=/path/in/container \
nginx:alpine
In this example, no name (source) is specified for the volume, so a new volume
is created for each task. This guarantees that each task gets its own volume,
and volumes are not shared between tasks. Anonymous volumes are removed after
the task using them is complete.
Create a service that uses a bind-mounted host directory
The following example bind-mounts a host directory at /path/in/container in
the containers backing the service:
$ docker service create \
--name my-service \
--mount type=bind,source=/path/on/host,destination=/path/in/container \
nginx:alpine
Set service mode (--mode)
The service mode determines whether this is a replicated service or a global service. A replicated service runs as many tasks as specified, while a global service runs on each active node in the swarm.
The following command creates a global service:
$ docker service create \
--name redis_2 \
--mode global \
redis:3.0.6
Specify service constraints (--constraint)
You can limit the set of nodes where a task can be scheduled by defining constraint expressions. Multiple constraints find nodes that satisfy every expression (AND match). Constraints can match node or Docker Engine labels as follows:
| node attribute | matches | example |
|---|---|---|
| node.id | node ID | node.id == 2ivku8v2gvtg4 |
| node.hostname | node hostname | node.hostname != node-2 |
| node.role | node role: manager | node.role == manager |
| node.labels | user defined node labels | node.labels.security == high |
| engine.labels | Docker Engine's labels | engine.labels.operatingsystem == ubuntu 14.04 |
engine.labels apply to Docker Engine labels like operating system,
drivers, etc. Swarm administrators add node.labels for operational purposes by
using the docker node update command.
For example, the following limits tasks for the redis service to nodes where the node type label equals queue:
$ docker service create \
--name redis_2 \
--constraint 'node.labels.type == queue' \
redis:3.0.6
Attach a service to an existing network (--network)
You can use overlay networks to connect one or more services within the swarm.
First, create an overlay network on a manager node the docker network create command:
$ docker network create --driver overlay my-network
etjpu59cykrptrgw0z0hk5snf
After you create an overlay network in swarm mode, all manager nodes have access to the network.
When you create a service and pass the --network flag to attach the service to the overlay network:
$ docker service create \
--replicas 3 \
--network my-network \
--name my-web \
nginx
716thylsndqma81j6kkkb5aus
The swarm extends my-network to each node running the service.
Containers on the same network can access each other using service discovery.
Publish service ports externally to the swarm (-p, --publish)
You can publish service ports to make them available externally to the swarm
using the --publish flag:
$ docker service create --publish <TARGET-PORT>:<SERVICE-PORT> nginx
For example:
$ docker service create --name my_web --replicas 3 --publish 8080:80 nginx
When you publish a service port, the swarm routing mesh makes the service accessible at the target port on every node regardless if there is a task for the service running on the node. For more information refer to Use swarm mode routing mesh.