Class ContainerDefinition

java.lang.Object
software.amazon.awssdk.services.ecs.model.ContainerDefinition
All Implemented Interfaces:
Serializable, SdkPojo, ToCopyableBuilder<ContainerDefinition.Builder,ContainerDefinition>
@Generated("software.amazon.awssdk:codegen") public final class ContainerDefinition extends Object implements SdkPojo, Serializable, ToCopyableBuilder<ContainerDefinition.Builder,ContainerDefinition>

Container definitions are used in task definitions to describe the different containers that are launched as part of a task.

See Also:

  • Method Details

    • name

      public final String name()

      The name of a container. If you're linking multiple containers together in a task definition, the name of one container can be entered in the links of another container to connect the containers. Up to 255 letters (uppercase and lowercase), numbers, underscores, and hyphens are allowed. This parameter maps to name in the docker container create command and the --name option to docker run.

      Returns:
      The name of a container. If you're linking multiple containers together in a task definition, the name of one container can be entered in the links of another container to connect the containers. Up to 255 letters (uppercase and lowercase), numbers, underscores, and hyphens are allowed. This parameter maps to name in the docker container create command and the --name option to docker run.

    • image

      public final String image()

      The image used to start a container. This string is passed directly to the Docker daemon. By default, images in the Docker Hub registry are available. Other repositories are specified with either repository-url/image:tag or repository-url/image@digest . For images using tags (repository-url/image:tag), up to 255 characters total are allowed, including letters (uppercase and lowercase), numbers, hyphens, underscores, colons, periods, forward slashes, and number signs (#). For images using digests (repository-url/image@digest), the 255 character limit applies only to the repository URL and image name (everything before the @ sign). The only supported hash function is sha256, and the hash value after sha256: must be exactly 64 characters (only letters A-F, a-f, and numbers 0-9 are allowed). This parameter maps to Image in the docker container create command and the IMAGE parameter of docker run.

      • When a new task starts, the Amazon ECS container agent pulls the latest version of the specified image and tag for the container to use. However, subsequent updates to a repository image aren't propagated to already running tasks.

      • Images in Amazon ECR repositories can be specified by either using the full registry/repository:tag or registry/repository@digest. For example, 012345678910.dkr.ecr.<region-name>.amazonaws.com/<repository-name>:latest or 012345678910.dkr.ecr.<region-name>.amazonaws.com/<repository-name>@sha256:94afd1f2e64d908bc90dbca0035a5b567EXAMPLE .

      • Images in official repositories on Docker Hub use a single name (for example, ubuntu or mongo).

      • Images in other repositories on Docker Hub are qualified with an organization name (for example, amazon/amazon-ecs-agent).

      • Images in other online repositories are qualified further by a domain name (for example, quay.io/assemblyline/ubuntu).

      Returns:
      The image used to start a container. This string is passed directly to the Docker daemon. By default, images in the Docker Hub registry are available. Other repositories are specified with either repository-url/image:tag or repository-url/image@digest . For images using tags (repository-url/image:tag), up to 255 characters total are allowed, including letters (uppercase and lowercase), numbers, hyphens, underscores, colons, periods, forward slashes, and number signs (#). For images using digests (repository-url/image@digest), the 255 character limit applies only to the repository URL and image name (everything before the @ sign). The only supported hash function is sha256, and the hash value after sha256: must be exactly 64 characters (only letters A-F, a-f, and numbers 0-9 are allowed). This parameter maps to Image in the docker container create command and the IMAGE parameter of docker run.

      • When a new task starts, the Amazon ECS container agent pulls the latest version of the specified image and tag for the container to use. However, subsequent updates to a repository image aren't propagated to already running tasks.

      • Images in Amazon ECR repositories can be specified by either using the full registry/repository:tag or registry/repository@digest. For example, 012345678910.dkr.ecr.<region-name>.amazonaws.com/<repository-name>:latest or 012345678910.dkr.ecr.<region-name>.amazonaws.com/<repository-name>@sha256:94afd1f2e64d908bc90dbca0035a5b567EXAMPLE .

      • Images in official repositories on Docker Hub use a single name (for example, ubuntu or mongo).

      • Images in other repositories on Docker Hub are qualified with an organization name (for example, amazon/amazon-ecs-agent).

      • Images in other online repositories are qualified further by a domain name (for example, quay.io/assemblyline/ubuntu).

    • repositoryCredentials

      public final RepositoryCredentials repositoryCredentials()

      The private repository authentication credentials to use.

      Returns:
      The private repository authentication credentials to use.

    • cpu

      public final Integer cpu()

      The number of cpu units reserved for the container. This parameter maps to CpuShares in the docker container create commandand the --cpu-shares option to docker run.

      This field is optional for tasks using the Fargate launch type, and the only requirement is that the total amount of CPU reserved for all containers within a task be lower than the task-level cpu value.

      You can determine the number of CPU units that are available per EC2 instance type by multiplying the vCPUs listed for that instance type on the Amazon EC2 Instances detail page by 1,024.

      Linux containers share unallocated CPU units with other containers on the container instance with the same ratio as their allocated amount. For example, if you run a single-container task on a single-core instance type with 512 CPU units specified for that container, and that's the only task running on the container instance, that container could use the full 1,024 CPU unit share at any given time. However, if you launched another copy of the same task on that container instance, each task is guaranteed a minimum of 512 CPU units when needed. Moreover, each container could float to higher CPU usage if the other container was not using it. If both tasks were 100% active all of the time, they would be limited to 512 CPU units.

      On Linux container instances, the Docker daemon on the container instance uses the CPU value to calculate the relative CPU share ratios for running containers. The minimum valid CPU share value that the Linux kernel allows is 2, and the maximum valid CPU share value that the Linux kernel allows is 262144. However, the CPU parameter isn't required, and you can use CPU values below 2 or above 262144 in your container definitions. For CPU values below 2 (including null) or above 262144, the behavior varies based on your Amazon ECS container agent version:

      • Agent versions less than or equal to 1.1.0: Null and zero CPU values are passed to Docker as 0, which Docker then converts to 1,024 CPU shares. CPU values of 1 are passed to Docker as 1, which the Linux kernel converts to two CPU shares.

      • Agent versions greater than or equal to 1.2.0: Null, zero, and CPU values of 1 are passed to Docker as 2.

      • Agent versions greater than or equal to 1.84.0: CPU values greater than 256 vCPU are passed to Docker as 256, which is equivalent to 262144 CPU shares.

      On Windows container instances, the CPU limit is enforced as an absolute limit, or a quota. Windows containers only have access to the specified amount of CPU that's described in the task definition. A null or zero CPU value is passed to Docker as 0, which Windows interprets as 1% of one CPU.

      Returns:
      The number of cpu units reserved for the container. This parameter maps to CpuShares in the docker container create commandand the --cpu-shares option to docker run.

      This field is optional for tasks using the Fargate launch type, and the only requirement is that the total amount of CPU reserved for all containers within a task be lower than the task-level cpu value.

      You can determine the number of CPU units that are available per EC2 instance type by multiplying the vCPUs listed for that instance type on the Amazon EC2 Instances detail page by 1,024.

      Linux containers share unallocated CPU units with other containers on the container instance with the same ratio as their allocated amount. For example, if you run a single-container task on a single-core instance type with 512 CPU units specified for that container, and that's the only task running on the container instance, that container could use the full 1,024 CPU unit share at any given time. However, if you launched another copy of the same task on that container instance, each task is guaranteed a minimum of 512 CPU units when needed. Moreover, each container could float to higher CPU usage if the other container was not using it. If both tasks were 100% active all of the time, they would be limited to 512 CPU units.

      On Linux container instances, the Docker daemon on the container instance uses the CPU value to calculate the relative CPU share ratios for running containers. The minimum valid CPU share value that the Linux kernel allows is 2, and the maximum valid CPU share value that the Linux kernel allows is 262144. However, the CPU parameter isn't required, and you can use CPU values below 2 or above 262144 in your container definitions. For CPU values below 2 (including null) or above 262144, the behavior varies based on your Amazon ECS container agent version:

      • Agent versions less than or equal to 1.1.0: Null and zero CPU values are passed to Docker as 0, which Docker then converts to 1,024 CPU shares. CPU values of 1 are passed to Docker as 1, which the Linux kernel converts to two CPU shares.

      • Agent versions greater than or equal to 1.2.0: Null, zero, and CPU values of 1 are passed to Docker as 2.

      • Agent versions greater than or equal to 1.84.0: CPU values greater than 256 vCPU are passed to Docker as 256, which is equivalent to 262144 CPU shares.

      On Windows container instances, the CPU limit is enforced as an absolute limit, or a quota. Windows containers only have access to the specified amount of CPU that's described in the task definition. A null or zero CPU value is passed to Docker as 0, which Windows interprets as 1% of one CPU.

    • memory

      public final Integer memory()

      The amount (in MiB) of memory to present to the container. If your container attempts to exceed the memory specified here, the container is killed. The total amount of memory reserved for all containers within a task must be lower than the task memory value, if one is specified. This parameter maps to Memory in the docker container create command and the --memory option to docker run.

      If using the Fargate launch type, this parameter is optional.

      If using the EC2 launch type, you must specify either a task-level memory value or a container-level memory value. If you specify both a container-level memory and memoryReservation value, memory must be greater than memoryReservation. If you specify memoryReservation, then that value is subtracted from the available memory resources for the container instance where the container is placed. Otherwise, the value of memory is used.

      The Docker 20.10.0 or later daemon reserves a minimum of 6 MiB of memory for a container. So, don't specify less than 6 MiB of memory for your containers.

      The Docker 19.03.13-ce or earlier daemon reserves a minimum of 4 MiB of memory for a container. So, don't specify less than 4 MiB of memory for your containers.

      Returns:
      The amount (in MiB) of memory to present to the container. If your container attempts to exceed the memory specified here, the container is killed. The total amount of memory reserved for all containers within a task must be lower than the task memory value, if one is specified. This parameter maps to Memory in the docker container create command and the --memory option to docker run.

      If using the Fargate launch type, this parameter is optional.

      If using the EC2 launch type, you must specify either a task-level memory value or a container-level memory value. If you specify both a container-level memory and memoryReservation value, memory must be greater than memoryReservation. If you specify memoryReservation, then that value is subtracted from the available memory resources for the container instance where the container is placed. Otherwise, the value of memory is used.

      The Docker 20.10.0 or later daemon reserves a minimum of 6 MiB of memory for a container. So, don't specify less than 6 MiB of memory for your containers.

      The Docker 19.03.13-ce or earlier daemon reserves a minimum of 4 MiB of memory for a container. So, don't specify less than 4 MiB of memory for your containers.

    • memoryReservation

      public final Integer memoryReservation()

      The soft limit (in MiB) of memory to reserve for the container. When system memory is under heavy contention, Docker attempts to keep the container memory to this soft limit. However, your container can consume more memory when it needs to, up to either the hard limit specified with the memory parameter (if applicable), or all of the available memory on the container instance, whichever comes first. This parameter maps to MemoryReservation in the docker container create command and the --memory-reservation option to docker run.

      If a task-level memory value is not specified, you must specify a non-zero integer for one or both of memory or memoryReservation in a container definition. If you specify both, memory must be greater than memoryReservation. If you specify memoryReservation, then that value is subtracted from the available memory resources for the container instance where the container is placed. Otherwise, the value of memory is used.

      For example, if your container normally uses 128 MiB of memory, but occasionally bursts to 256 MiB of memory for short periods of time, you can set a memoryReservation of 128 MiB, and a memory hard limit of 300 MiB. This configuration would allow the container to only reserve 128 MiB of memory from the remaining resources on the container instance, but also allow the container to consume more memory resources when needed.

      The Docker 20.10.0 or later daemon reserves a minimum of 6 MiB of memory for a container. So, don't specify less than 6 MiB of memory for your containers.

      The Docker 19.03.13-ce or earlier daemon reserves a minimum of 4 MiB of memory for a container. So, don't specify less than 4 MiB of memory for your containers.

      Returns:
      The soft limit (in MiB) of memory to reserve for the container. When system memory is under heavy contention, Docker attempts to keep the container memory to this soft limit. However, your container can consume more memory when it needs to, up to either the hard limit specified with the memory parameter (if applicable), or all of the available memory on the container instance, whichever comes first. This parameter maps to MemoryReservation in the docker container create command and the --memory-reservation option to docker run.

      If a task-level memory value is not specified, you must specify a non-zero integer for one or both of memory or memoryReservation in a container definition. If you specify both, memory must be greater than memoryReservation. If you specify memoryReservation, then that value is subtracted from the available memory resources for the container instance where the container is placed. Otherwise, the value of memory is used.

      For example, if your container normally uses 128 MiB of memory, but occasionally bursts to 256 MiB of memory for short periods of time, you can set a memoryReservation of 128 MiB, and a memory hard limit of 300 MiB. This configuration would allow the container to only reserve 128 MiB of memory from the remaining resources on the container instance, but also allow the container to consume more memory resources when needed.

      The Docker 20.10.0 or later daemon reserves a minimum of 6 MiB of memory for a container. So, don't specify less than 6 MiB of memory for your containers.

      The Docker 19.03.13-ce or earlier daemon reserves a minimum of 4 MiB of memory for a container. So, don't specify less than 4 MiB of memory for your containers.

    • hasLinks

      public final boolean hasLinks()
      For responses, this returns true if the service returned a value for the Links property. This DOES NOT check that the value is non-empty (for which, you should check the isEmpty() method on the property). This is useful because the SDK will never return a null collection or map, but you may need to differentiate between the service returning nothing (or null) and the service returning an empty collection or map. For requests, this returns true if a value for the property was specified in the request builder, and false if a value was not specified.

    • links

      public final List<String> links()

      The links parameter allows containers to communicate with each other without the need for port mappings. This parameter is only supported if the network mode of a task definition is bridge. The name:internalName construct is analogous to name:alias in Docker links. Up to 255 letters (uppercase and lowercase), numbers, underscores, and hyphens are allowed.. This parameter maps to Links in the docker container create command and the --link option to docker run.

      This parameter is not supported for Windows containers.

      Containers that are collocated on a single container instance may be able to communicate with each other without requiring links or host port mappings. Network isolation is achieved on the container instance using security groups and VPC settings.

      Attempts to modify the collection returned by this method will result in an UnsupportedOperationException.

      This method will never return null. If you would like to know whether the service returned this field (so that you can differentiate between null and empty), you can use the hasLinks() method.

      Returns:
      The links parameter allows containers to communicate with each other without the need for port mappings. This parameter is only supported if the network mode of a task definition is bridge. The name:internalName construct is analogous to name:alias in Docker links. Up to 255 letters (uppercase and lowercase), numbers, underscores, and hyphens are allowed.. This parameter maps to Links in the docker container create command and the --link option to docker run.

      This parameter is not supported for Windows containers.

      Containers that are collocated on a single container instance may be able to communicate with each other without requiring links or host port mappings. Network isolation is achieved on the container instance using security groups and VPC settings.

    • hasPortMappings

      public final boolean hasPortMappings()
      For responses, this returns true if the service returned a value for the PortMappings property. This DOES NOT check that the value is non-empty (for which, you should check the isEmpty() method on the property). This is useful because the SDK will never return a null collection or map, but you may need to differentiate between the service returning nothing (or null) and the service returning an empty collection or map. For requests, this returns true if a value for the property was specified in the request builder, and false if a value was not specified.

    • portMappings

      public final List<PortMapping> portMappings()

      The list of port mappings for the container. Port mappings allow containers to access ports on the host container instance to send or receive traffic.

      For task definitions that use the awsvpc network mode, only specify the containerPort. The hostPort can be left blank or it must be the same value as the containerPort.

      Port mappings on Windows use the NetNAT gateway address rather than localhost. There's no loopback for port mappings on Windows, so you can't access a container's mapped port from the host itself.

      This parameter maps to PortBindings in the docker container create command and the --publish option to docker run. If the network mode of a task definition is set to none , then you can't specify port mappings. If the network mode of a task definition is set to host, then host ports must either be undefined or they must match the container port in the port mapping.

      After a task reaches the RUNNING status, manual and automatic host and container port assignments are visible in the Network Bindings section of a container description for a selected task in the Amazon ECS console. The assignments are also visible in the networkBindings section DescribeTasks responses.

      Attempts to modify the collection returned by this method will result in an UnsupportedOperationException.

      This method will never return null. If you would like to know whether the service returned this field (so that you can differentiate between null and empty), you can use the hasPortMappings() method.

      Returns:
      The list of port mappings for the container. Port mappings allow containers to access ports on the host container instance to send or receive traffic.

      For task definitions that use the awsvpc network mode, only specify the containerPort. The hostPort can be left blank or it must be the same value as the containerPort.

      Port mappings on Windows use the NetNAT gateway address rather than localhost. There's no loopback for port mappings on Windows, so you can't access a container's mapped port from the host itself.

      This parameter maps to PortBindings in the docker container create command and the --publish option to docker run. If the network mode of a task definition is set to none, then you can't specify port mappings. If the network mode of a task definition is set to host, then host ports must either be undefined or they must match the container port in the port mapping.

      After a task reaches the RUNNING status, manual and automatic host and container port assignments are visible in the Network Bindings section of a container description for a selected task in the Amazon ECS console. The assignments are also visible in the networkBindings section DescribeTasks responses.

    • essential

      public final Boolean essential()

      If the essential parameter of a container is marked as true, and that container fails or stops for any reason, all other containers that are part of the task are stopped. If the essential parameter of a container is marked as false, its failure doesn't affect the rest of the containers in a task. If this parameter is omitted, a container is assumed to be essential.

      All tasks must have at least one essential container. If you have an application that's composed of multiple containers, group containers that are used for a common purpose into components, and separate the different components into multiple task definitions. For more information, see Application Architecture in the Amazon Elastic Container Service Developer Guide.

      Returns:
      If the essential parameter of a container is marked as true, and that container fails or stops for any reason, all other containers that are part of the task are stopped. If the essential parameter of a container is marked as false, its failure doesn't affect the rest of the containers in a task. If this parameter is omitted, a container is assumed to be essential.

      All tasks must have at least one essential container. If you have an application that's composed of multiple containers, group containers that are used for a common purpose into components, and separate the different components into multiple task definitions. For more information, see Application Architecture in the Amazon Elastic Container Service Developer Guide.

    • restartPolicy

      public final ContainerRestartPolicy restartPolicy()

      The restart policy for a container. When you set up a restart policy, Amazon ECS can restart the container without needing to replace the task. For more information, see Restart individual containers in Amazon ECS tasks with container restart policies in the Amazon Elastic Container Service Developer Guide.

      Returns:
      The restart policy for a container. When you set up a restart policy, Amazon ECS can restart the container without needing to replace the task. For more information, see Restart individual containers in Amazon ECS tasks with container restart policies in the Amazon Elastic Container Service Developer Guide.

    • hasEntryPoint

      public final boolean hasEntryPoint()
      For responses, this returns true if the service returned a value for the EntryPoint property. This DOES NOT check that the value is non-empty (for which, you should check the isEmpty() method on the property). This is useful because the SDK will never return a null collection or map, but you may need to differentiate between the service returning nothing (or null) and the service returning an empty collection or map. For requests, this returns true if a value for the property was specified in the request builder, and false if a value was not specified.

    • entryPoint

      public final List<String> entryPoint()

      Early versions of the Amazon ECS container agent don't properly handle entryPoint parameters. If you have problems using entryPoint, update your container agent or enter your commands and arguments as command array items instead.

      The entry point that's passed to the container. This parameter maps to Entrypoint in the docker container create command and the --entrypoint option to docker run.

      Attempts to modify the collection returned by this method will result in an UnsupportedOperationException.

      This method will never return null. If you would like to know whether the service returned this field (so that you can differentiate between null and empty), you can use the hasEntryPoint() method.

      Returns:

      Early versions of the Amazon ECS container agent don't properly handle entryPoint parameters. If you have problems using entryPoint, update your container agent or enter your commands and arguments as command array items instead.

      The entry point that's passed to the container. This parameter maps to Entrypoint in the docker container create command and the --entrypoint option to docker run.

    • hasCommand

      public final boolean hasCommand()
      For responses, this returns true if the service returned a value for the Command property. This DOES NOT check that the value is non-empty (for which, you should check the isEmpty() method on the property). This is useful because the SDK will never return a null collection or map, but you may need to differentiate between the service returning nothing (or null) and the service returning an empty collection or map. For requests, this returns true if a value for the property was specified in the request builder, and false if a value was not specified.

    • command

      public final List<String> command()

      The command that's passed to the container. This parameter maps to Cmd in the docker container create command and the COMMAND parameter to docker run. If there are multiple arguments, each argument is a separated string in the array.

      Attempts to modify the collection returned by this method will result in an UnsupportedOperationException.

      This method will never return null. If you would like to know whether the service returned this field (so that you can differentiate between null and empty), you can use the hasCommand() method.

      Returns:
      The command that's passed to the container. This parameter maps to Cmd in the docker container create command and the COMMAND parameter to docker run. If there are multiple arguments, each argument is a separated string in the array.

    • hasEnvironment

      public final boolean hasEnvironment()
      For responses, this returns true if the service returned a value for the Environment property. This DOES NOT check that the value is non-empty (for which, you should check the isEmpty() method on the property). This is useful because the SDK will never return a null collection or map, but you may need to differentiate between the service returning nothing (or null) and the service returning an empty collection or map. For requests, this returns true if a value for the property was specified in the request builder, and false if a value was not specified.

    • environment

      public final List<KeyValuePair> environment()

      The environment variables to pass to a container. This parameter maps to Env in the docker container create command and the --env option to docker run.

      We don't recommend that you use plaintext environment variables for sensitive information, such as credential data.

      Attempts to modify the collection returned by this method will result in an UnsupportedOperationException.

      This method will never return null. If you would like to know whether the service returned this field (so that you can differentiate between null and empty), you can use the hasEnvironment() method.

      Returns:
      The environment variables to pass to a container. This parameter maps to Env in the docker container create command and the --env option to docker run.

      We don't recommend that you use plaintext environment variables for sensitive information, such as credential data.

    • hasEnvironmentFiles

      public final boolean hasEnvironmentFiles()
      For responses, this returns true if the service returned a value for the EnvironmentFiles property. This DOES NOT check that the value is non-empty (for which, you should check the isEmpty() method on the property). This is useful because the SDK will never return a null collection or map, but you may need to differentiate between the service returning nothing (or null) and the service returning an empty collection or map. For requests, this returns true if a value for the property was specified in the request builder, and false if a value was not specified.

    • environmentFiles

      public final List<EnvironmentFile> environmentFiles()

      A list of files containing the environment variables to pass to a container. This parameter maps to the --env-file option to docker run.

      You can specify up to ten environment files. The file must have a .env file extension. Each line in an environment file contains an environment variable in VARIABLE=VALUE format. Lines beginning with # are treated as comments and are ignored.

      If there are environment variables specified using the environment parameter in a container definition, they take precedence over the variables contained within an environment file. If multiple environment files are specified that contain the same variable, they're processed from the top down. We recommend that you use unique variable names. For more information, see Specifying Environment Variables in the Amazon Elastic Container Service Developer Guide.

      Attempts to modify the collection returned by this method will result in an UnsupportedOperationException.

      This method will never return null. If you would like to know whether the service returned this field (so that you can differentiate between null and empty), you can use the hasEnvironmentFiles() method.

      Returns:
      A list of files containing the environment variables to pass to a container. This parameter maps to the --env-file option to docker run.

      You can specify up to ten environment files. The file must have a .env file extension. Each line in an environment file contains an environment variable in VARIABLE=VALUE format. Lines beginning with # are treated as comments and are ignored.

      If there are environment variables specified using the environment parameter in a container definition, they take precedence over the variables contained within an environment file. If multiple environment files are specified that contain the same variable, they're processed from the top down. We recommend that you use unique variable names. For more information, see Specifying Environment Variables in the Amazon Elastic Container Service Developer Guide.

    • hasMountPoints

      public final boolean hasMountPoints()
      For responses, this returns true if the service returned a value for the MountPoints property. This DOES NOT check that the value is non-empty (for which, you should check the isEmpty() method on the property). This is useful because the SDK will never return a null collection or map, but you may need to differentiate between the service returning nothing (or null) and the service returning an empty collection or map. For requests, this returns true if a value for the property was specified in the request builder, and false if a value was not specified.

    • mountPoints

      public final List<MountPoint> mountPoints()

      The mount points for data volumes in your container.

      This parameter maps to Volumes in the docker container create command and the --volume option to docker run.

      Windows containers can mount whole directories on the same drive as $env:ProgramData. Windows containers can't mount directories on a different drive, and mount point can't be across drives.

      Attempts to modify the collection returned by this method will result in an UnsupportedOperationException.

      This method will never return null. If you would like to know whether the service returned this field (so that you can differentiate between null and empty), you can use the hasMountPoints() method.

      Returns:
      The mount points for data volumes in your container.

      This parameter maps to Volumes in the docker container create command and the --volume option to docker run.

      Windows containers can mount whole directories on the same drive as $env:ProgramData. Windows containers can't mount directories on a different drive, and mount point can't be across drives.

    • hasVolumesFrom

      public final boolean hasVolumesFrom()
      For responses, this returns true if the service returned a value for the VolumesFrom property. This DOES NOT check that the value is non-empty (for which, you should check the isEmpty() method on the property). This is useful because the SDK will never return a null collection or map, but you may need to differentiate between the service returning nothing (or null) and the service returning an empty collection or map. For requests, this returns true if a value for the property was specified in the request builder, and false if a value was not specified.

    • volumesFrom

      public final List<VolumeFrom> volumesFrom()

      Data volumes to mount from another container. This parameter maps to VolumesFrom in the docker container create command and the --volumes-from option to docker run.

      Attempts to modify the collection returned by this method will result in an UnsupportedOperationException.

      This method will never return null. If you would like to know whether the service returned this field (so that you can differentiate between null and empty), you can use the hasVolumesFrom() method.

      Returns:
      Data volumes to mount from another container. This parameter maps to VolumesFrom in the docker container create command and the --volumes-from option to docker run.

    • linuxParameters

      public final LinuxParameters linuxParameters()

      Linux-specific modifications that are applied to the default Docker container configuration, such as Linux kernel capabilities. For more information see KernelCapabilities.

      This parameter is not supported for Windows containers.

      Returns:
      Linux-specific modifications that are applied to the default Docker container configuration, such as Linux kernel capabilities. For more information see KernelCapabilities.

      This parameter is not supported for Windows containers.

    • hasSecrets

      public final boolean hasSecrets()
      For responses, this returns true if the service returned a value for the Secrets property. This DOES NOT check that the value is non-empty (for which, you should check the isEmpty() method on the property). This is useful because the SDK will never return a null collection or map, but you may need to differentiate between the service returning nothing (or null) and the service returning an empty collection or map. For requests, this returns true if a value for the property was specified in the request builder, and false if a value was not specified.

    • secrets

      public final List<Secret> secrets()

      The secrets to pass to the container. For more information, see Specifying Sensitive Data in the Amazon Elastic Container Service Developer Guide.

      Attempts to modify the collection returned by this method will result in an UnsupportedOperationException.

      This method will never return null. If you would like to know whether the service returned this field (so that you can differentiate between null and empty), you can use the hasSecrets() method.

      Returns:
      The secrets to pass to the container. For more information, see Specifying Sensitive Data in the Amazon Elastic Container Service Developer Guide.

    • hasDependsOn

      public final boolean hasDependsOn()
      For responses, this returns true if the service returned a value for the DependsOn property. This DOES NOT check that the value is non-empty (for which, you should check the isEmpty() method on the property). This is useful because the SDK will never return a null collection or map, but you may need to differentiate between the service returning nothing (or null) and the service returning an empty collection or map. For requests, this returns true if a value for the property was specified in the request builder, and false if a value was not specified.

    • dependsOn

      public final List<ContainerDependency> dependsOn()

      The dependencies defined for container startup and shutdown. A container can contain multiple dependencies on other containers in a task definition. When a dependency is defined for container startup, for container shutdown it is reversed.

      For tasks using the EC2 launch type, the container instances require at least version 1.26.0 of the container agent to turn on container dependencies. However, we recommend using the latest container agent version. For information about checking your agent version and updating to the latest version, see Updating the Amazon ECS Container Agent in the Amazon Elastic Container Service Developer Guide. If you're using an Amazon ECS-optimized Linux AMI, your instance needs at least version 1.26.0-1 of the ecs-init package. If your container instances are launched from version 20190301 or later, then they contain the required versions of the container agent and ecs-init. For more information, see Amazon ECS-optimized Linux AMI in the Amazon Elastic Container Service Developer Guide.

      For tasks using the Fargate launch type, the task or service requires the following platforms:

      • Linux platform version 1.3.0 or later.

      • Windows platform version 1.0.0 or later.

      Attempts to modify the collection returned by this method will result in an UnsupportedOperationException.

      This method will never return null. If you would like to know whether the service returned this field (so that you can differentiate between null and empty), you can use the hasDependsOn() method.

      Returns:
      The dependencies defined for container startup and shutdown. A container can contain multiple dependencies on other containers in a task definition. When a dependency is defined for container startup, for container shutdown it is reversed.

      For tasks using the EC2 launch type, the container instances require at least version 1.26.0 of the container agent to turn on container dependencies. However, we recommend using the latest container agent version. For information about checking your agent version and updating to the latest version, see Updating the Amazon ECS Container Agent in the Amazon Elastic Container Service Developer Guide. If you're using an Amazon ECS-optimized Linux AMI, your instance needs at least version 1.26.0-1 of the ecs-init package. If your container instances are launched from version 20190301 or later, then they contain the required versions of the container agent and ecs-init. For more information, see Amazon ECS-optimized Linux AMI in the Amazon Elastic Container Service Developer Guide.

      For tasks using the Fargate launch type, the task or service requires the following platforms:

      • Linux platform version 1.3.0 or later.

      • Windows platform version 1.0.0 or later.

    • startTimeout

      public final Integer startTimeout()

      Time duration (in seconds) to wait before giving up on resolving dependencies for a container. For example, you specify two containers in a task definition with containerA having a dependency on containerB reaching a COMPLETE, SUCCESS, or HEALTHY status. If a startTimeout value is specified for containerB and it doesn't reach the desired status within that time then containerA gives up and not start. This results in the task transitioning to a STOPPED state.

      When the ECS_CONTAINER_START_TIMEOUT container agent configuration variable is used, it's enforced independently from this start timeout value.

      For tasks using the Fargate launch type, the task or service requires the following platforms:

      • Linux platform version 1.3.0 or later.

      • Windows platform version 1.0.0 or later.

      For tasks using the EC2 launch type, your container instances require at least version 1.26.0 of the container agent to use a container start timeout value. However, we recommend using the latest container agent version. For information about checking your agent version and updating to the latest version, see Updating the Amazon ECS Container Agent in the Amazon Elastic Container Service Developer Guide. If you're using an Amazon ECS-optimized Linux AMI, your instance needs at least version 1.26.0-1 of the ecs-init package. If your container instances are launched from version 20190301 or later, then they contain the required versions of the container agent and ecs-init. For more information, see Amazon ECS-optimized Linux AMI in the Amazon Elastic Container Service Developer Guide.

      The valid values for Fargate are 2-120 seconds.

      Returns:
      Time duration (in seconds) to wait before giving up on resolving dependencies for a container. For example, you specify two containers in a task definition with containerA having a dependency on containerB reaching a COMPLETE, SUCCESS, or HEALTHY status. If a startTimeout value is specified for containerB and it doesn't reach the desired status within that time then containerA gives up and not start. This results in the task transitioning to a STOPPED state.

      When the ECS_CONTAINER_START_TIMEOUT container agent configuration variable is used, it's enforced independently from this start timeout value.

      For tasks using the Fargate launch type, the task or service requires the following platforms:

      • Linux platform version 1.3.0 or later.

      • Windows platform version 1.0.0 or later.

      For tasks using the EC2 launch type, your container instances require at least version 1.26.0 of the container agent to use a container start timeout value. However, we recommend using the latest container agent version. For information about checking your agent version and updating to the latest version, see Updating the Amazon ECS Container Agent in the Amazon Elastic Container Service Developer Guide. If you're using an Amazon ECS-optimized Linux AMI, your instance needs at least version 1.26.0-1 of the ecs-init package. If your container instances are launched from version 20190301 or later, then they contain the required versions of the container agent and ecs-init. For more information, see Amazon ECS-optimized Linux AMI in the Amazon Elastic Container Service Developer Guide.

      The valid values for Fargate are 2-120 seconds.

    • stopTimeout

      public final Integer stopTimeout()

      Time duration (in seconds) to wait before the container is forcefully killed if it doesn't exit normally on its own.

      For tasks using the Fargate launch type, the task or service requires the following platforms:

      • Linux platform version 1.3.0 or later.

      • Windows platform version 1.0.0 or later.

      For tasks that use the Fargate launch type, the max stop timeout value is 120 seconds and if the parameter is not specified, the default value of 30 seconds is used.

      For tasks that use the EC2 launch type, if the stopTimeout parameter isn't specified, the value set for the Amazon ECS container agent configuration variable ECS_CONTAINER_STOP_TIMEOUT is used. If neither the stopTimeout parameter or the ECS_CONTAINER_STOP_TIMEOUT agent configuration variable are set, then the default values of 30 seconds for Linux containers and 30 seconds on Windows containers are used. Your container instances require at least version 1.26.0 of the container agent to use a container stop timeout value. However, we recommend using the latest container agent version. For information about checking your agent version and updating to the latest version, see Updating the Amazon ECS Container Agent in the Amazon Elastic Container Service Developer Guide. If you're using an Amazon ECS-optimized Linux AMI, your instance needs at least version 1.26.0-1 of the ecs-init package. If your container instances are launched from version 20190301 or later, then they contain the required versions of the container agent and ecs-init. For more information, see Amazon ECS-optimized Linux AMI in the Amazon Elastic Container Service Developer Guide.

      The valid values for Fargate are 2-120 seconds.

      Returns:
      Time duration (in seconds) to wait before the container is forcefully killed if it doesn't exit normally on its own.

      For tasks using the Fargate launch type, the task or service requires the following platforms:

      • Linux platform version 1.3.0 or later.

      • Windows platform version 1.0.0 or later.

      For tasks that use the Fargate launch type, the max stop timeout value is 120 seconds and if the parameter is not specified, the default value of 30 seconds is used.

      For tasks that use the EC2 launch type, if the stopTimeout parameter isn't specified, the value set for the Amazon ECS container agent configuration variable ECS_CONTAINER_STOP_TIMEOUT is used. If neither the stopTimeout parameter or the ECS_CONTAINER_STOP_TIMEOUT agent configuration variable are set, then the default values of 30 seconds for Linux containers and 30 seconds on Windows containers are used. Your container instances require at least version 1.26.0 of the container agent to use a container stop timeout value. However, we recommend using the latest container agent version. For information about checking your agent version and updating to the latest version, see Updating the Amazon ECS Container Agent in the Amazon Elastic Container Service Developer Guide. If you're using an Amazon ECS-optimized Linux AMI, your instance needs at least version 1.26.0-1 of the ecs-init package. If your container instances are launched from version 20190301 or later, then they contain the required versions of the container agent and ecs-init. For more information, see Amazon ECS-optimized Linux AMI in the Amazon Elastic Container Service Developer Guide.

      The valid values for Fargate are 2-120 seconds.

    • versionConsistency

      public final VersionConsistency versionConsistency()

      Specifies whether Amazon ECS will resolve the container image tag provided in the container definition to an image digest. By default, the value is enabled. If you set the value for a container as disabled, Amazon ECS will not resolve the provided container image tag to a digest and will use the original image URI specified in the container definition for deployment. For more information about container image resolution, see Container image resolution in the Amazon ECS Developer Guide.

      If the service returns an enum value that is not available in the current SDK version, versionConsistency will return VersionConsistency.UNKNOWN_TO_SDK_VERSION. The raw value returned by the service is available from versionConsistencyAsString().

      Returns:
      Specifies whether Amazon ECS will resolve the container image tag provided in the container definition to an image digest. By default, the value is enabled. If you set the value for a container as disabled, Amazon ECS will not resolve the provided container image tag to a digest and will use the original image URI specified in the container definition for deployment. For more information about container image resolution, see Container image resolution in the Amazon ECS Developer Guide.
      See Also:

    • versionConsistencyAsString

      public final String versionConsistencyAsString()

      Specifies whether Amazon ECS will resolve the container image tag provided in the container definition to an image digest. By default, the value is enabled. If you set the value for a container as disabled, Amazon ECS will not resolve the provided container image tag to a digest and will use the original image URI specified in the container definition for deployment. For more information about container image resolution, see Container image resolution in the Amazon ECS Developer Guide.

      If the service returns an enum value that is not available in the current SDK version, versionConsistency will return VersionConsistency.UNKNOWN_TO_SDK_VERSION. The raw value returned by the service is available from versionConsistencyAsString().

      Returns:
      Specifies whether Amazon ECS will resolve the container image tag provided in the container definition to an image digest. By default, the value is enabled. If you set the value for a container as disabled, Amazon ECS will not resolve the provided container image tag to a digest and will use the original image URI specified in the container definition for deployment. For more information about container image resolution, see Container image resolution in the Amazon ECS Developer Guide.
      See Also:

    • hostname

      public final String hostname()

      The hostname to use for your container. This parameter maps to Hostname in the docker container create command and the --hostname option to docker run.

      The hostname parameter is not supported if you're using the awsvpc network mode.

      Returns:
      The hostname to use for your container. This parameter maps to Hostname in the docker container create command and the --hostname option to docker run.

      The hostname parameter is not supported if you're using the awsvpc network mode.

    • user

      public final String user()

      The user to use inside the container. This parameter maps to User in the docker container create command and the --user option to docker run.

      When running tasks using the host network mode, don't run containers using the root user (UID 0). We recommend using a non-root user for better security.

      You can specify the user using the following formats. If specifying a UID or GID, you must specify it as a positive integer.

      • user

      • user:group

      • uid

      • uid:gid

      • user:gid

      • uid:group

      This parameter is not supported for Windows containers.

      Returns:
      The user to use inside the container. This parameter maps to User in the docker container create command and the --user option to docker run.

      When running tasks using the host network mode, don't run containers using the root user (UID 0). We recommend using a non-root user for better security.

      You can specify the user using the following formats. If specifying a UID or GID, you must specify it as a positive integer.

      • user

      • user:group

      • uid

      • uid:gid

      • user:gid

      • uid:group

      This parameter is not supported for Windows containers.

    • workingDirectory

      public final String workingDirectory()

      The working directory to run commands inside the container in. This parameter maps to WorkingDir in the docker container create command and the --workdir option to docker run.

      Returns:
      The working directory to run commands inside the container in. This parameter maps to WorkingDir in the docker container create command and the --workdir option to docker run.

    • disableNetworking

      public final Boolean disableNetworking()

      When this parameter is true, networking is off within the container. This parameter maps to NetworkDisabled in the docker container create command.

      This parameter is not supported for Windows containers.

      Returns:
      When this parameter is true, networking is off within the container. This parameter maps to NetworkDisabled in the docker container create command.

      This parameter is not supported for Windows containers.

    • privileged

      public final Boolean privileged()

      When this parameter is true, the container is given elevated privileges on the host container instance (similar to the root user). This parameter maps to Privileged in the docker container create command and the --privileged option to docker run

      This parameter is not supported for Windows containers or tasks run on Fargate.

      Returns:
      When this parameter is true, the container is given elevated privileges on the host container instance (similar to the root user). This parameter maps to Privileged in the docker container create command and the --privileged option to docker run

      This parameter is not supported for Windows containers or tasks run on Fargate.

    • readonlyRootFilesystem

      public final Boolean readonlyRootFilesystem()

      When this parameter is true, the container is given read-only access to its root file system. This parameter maps to ReadonlyRootfs in the docker container create command and the --read-only option to docker run.

      This parameter is not supported for Windows containers.

      Returns:
      When this parameter is true, the container is given read-only access to its root file system. This parameter maps to ReadonlyRootfs in the docker container create command and the --read-only option to docker run.

      This parameter is not supported for Windows containers.

    • hasDnsServers

      public final boolean hasDnsServers()
      For responses, this returns true if the service returned a value for the DnsServers property. This DOES NOT check that the value is non-empty (for which, you should check the isEmpty() method on the property). This is useful because the SDK will never return a null collection or map, but you may need to differentiate between the service returning nothing (or null) and the service returning an empty collection or map. For requests, this returns true if a value for the property was specified in the request builder, and false if a value was not specified.

    • dnsServers

      public final List<String> dnsServers()

      A list of DNS servers that are presented to the container. This parameter maps to Dns in the docker container create command and the --dns option to docker run.

      This parameter is not supported for Windows containers.

      Attempts to modify the collection returned by this method will result in an UnsupportedOperationException.

      This method will never return null. If you would like to know whether the service returned this field (so that you can differentiate between null and empty), you can use the hasDnsServers() method.

      Returns:
      A list of DNS servers that are presented to the container. This parameter maps to Dns in the docker container create command and the --dns option to docker run.

      This parameter is not supported for Windows containers.

    • hasDnsSearchDomains

      public final boolean hasDnsSearchDomains()
      For responses, this returns true if the service returned a value for the DnsSearchDomains property. This DOES NOT check that the value is non-empty (for which, you should check the isEmpty() method on the property). This is useful because the SDK will never return a null collection or map, but you may need to differentiate between the service returning nothing (or null) and the service returning an empty collection or map. For requests, this returns true if a value for the property was specified in the request builder, and false if a value was not specified.

    • dnsSearchDomains

      public final List<String> dnsSearchDomains()

      A list of DNS search domains that are presented to the container. This parameter maps to DnsSearch in the docker container create command and the --dns-search option to docker run.

      This parameter is not supported for Windows containers.

      Attempts to modify the collection returned by this method will result in an UnsupportedOperationException.

      This method will never return null. If you would like to know whether the service returned this field (so that you can differentiate between null and empty), you can use the hasDnsSearchDomains() method.

      Returns:
      A list of DNS search domains that are presented to the container. This parameter maps to DnsSearch in the docker container create command and the --dns-search option to docker run.

      This parameter is not supported for Windows containers.

    • hasExtraHosts

      public final boolean hasExtraHosts()
      For responses, this returns true if the service returned a value for the ExtraHosts property. This DOES NOT check that the value is non-empty (for which, you should check the isEmpty() method on the property). This is useful because the SDK will never return a null collection or map, but you may need to differentiate between the service returning nothing (or null) and the service returning an empty collection or map. For requests, this returns true if a value for the property was specified in the request builder, and false if a value was not specified.

    • extraHosts

      public final List<HostEntry> extraHosts()

      A list of hostnames and IP address mappings to append to the /etc/hosts file on the container. This parameter maps to ExtraHosts in the docker container create command and the --add-host option to docker run.

      This parameter isn't supported for Windows containers or tasks that use the awsvpc network mode.

      Attempts to modify the collection returned by this method will result in an UnsupportedOperationException.

      This method will never return null. If you would like to know whether the service returned this field (so that you can differentiate between null and empty), you can use the hasExtraHosts() method.

      Returns:
      A list of hostnames and IP address mappings to append to the /etc/hosts file on the container. This parameter maps to ExtraHosts in the docker container create command and the --add-host option to docker run.

      This parameter isn't supported for Windows containers or tasks that use the awsvpc network mode.

    • hasDockerSecurityOptions

      public final boolean hasDockerSecurityOptions()
      For responses, this returns true if the service returned a value for the DockerSecurityOptions property. This DOES NOT check that the value is non-empty (for which, you should check the isEmpty() method on the property). This is useful because the SDK will never return a null collection or map, but you may need to differentiate between the service returning nothing (or null) and the service returning an empty collection or map. For requests, this returns true if a value for the property was specified in the request builder, and false if a value was not specified.

    • dockerSecurityOptions

      public final List<String> dockerSecurityOptions()

      A list of strings to provide custom configuration for multiple security systems. This field isn't valid for containers in tasks using the Fargate launch type.

      For Linux tasks on EC2, this parameter can be used to reference custom labels for SELinux and AppArmor multi-level security systems.

      For any tasks on EC2, this parameter can be used to reference a credential spec file that configures a container for Active Directory authentication. For more information, see Using gMSAs for Windows Containers and Using gMSAs for Linux Containers in the Amazon Elastic Container Service Developer Guide.

      This parameter maps to SecurityOpt in the docker container create command and the --security-opt option to docker run.

      The Amazon ECS container agent running on a container instance must register with the ECS_SELINUX_CAPABLE=true or ECS_APPARMOR_CAPABLE=true environment variables before containers placed on that instance can use these security options. For more information, see Amazon ECS Container Agent Configuration in the Amazon Elastic Container Service Developer Guide.

      Valid values: "no-new-privileges" | "apparmor:PROFILE" | "label:value" | "credentialspec:CredentialSpecFilePath"

      Attempts to modify the collection returned by this method will result in an UnsupportedOperationException.

      This method will never return null. If you would like to know whether the service returned this field (so that you can differentiate between null and empty), you can use the hasDockerSecurityOptions() method.

      Returns:
      A list of strings to provide custom configuration for multiple security systems. This field isn't valid for containers in tasks using the Fargate launch type.

      For Linux tasks on EC2, this parameter can be used to reference custom labels for SELinux and AppArmor multi-level security systems.

      For any tasks on EC2, this parameter can be used to reference a credential spec file that configures a container for Active Directory authentication. For more information, see Using gMSAs for Windows Containers and Using gMSAs for Linux Containers in the Amazon Elastic Container Service Developer Guide.

      This parameter maps to SecurityOpt in the docker container create command and the --security-opt option to docker run.

      The Amazon ECS container agent running on a container instance must register with the ECS_SELINUX_CAPABLE=true or ECS_APPARMOR_CAPABLE=true environment variables before containers placed on that instance can use these security options. For more information, see Amazon ECS Container Agent Configuration in the Amazon Elastic Container Service Developer Guide.

      Valid values: "no-new-privileges" | "apparmor:PROFILE" | "label:value" | "credentialspec:CredentialSpecFilePath"

    • interactive

      public final Boolean interactive()

      When this parameter is true, you can deploy containerized applications that require stdin or a tty to be allocated. This parameter maps to OpenStdin in the docker container create command and the --interactive option to docker run.

      Returns:
      When this parameter is true, you can deploy containerized applications that require stdin or a tty to be allocated. This parameter maps to OpenStdin in the docker container create command and the --interactive option to docker run.

    • pseudoTerminal

      public final Boolean pseudoTerminal()

      When this parameter is true, a TTY is allocated. This parameter maps to Tty in the docker container create command and the --tty option to docker run.

      Returns:
      When this parameter is true, a TTY is allocated. This parameter maps to Tty in the docker container create command and the --tty option to docker run.

    • hasDockerLabels

      public final boolean hasDockerLabels()
      For responses, this returns true if the service returned a value for the DockerLabels property. This DOES NOT check that the value is non-empty (for which, you should check the isEmpty() method on the property). This is useful because the SDK will never return a null collection or map, but you may need to differentiate between the service returning nothing (or null) and the service returning an empty collection or map. For requests, this returns true if a value for the property was specified in the request builder, and false if a value was not specified.

    • dockerLabels

      public final Map<String,String> dockerLabels()

      A key/value map of labels to add to the container. This parameter maps to Labels in the docker container create command and the --label option to docker run. This parameter requires version 1.18 of the Docker Remote API or greater on your container instance. To check the Docker Remote API version on your container instance, log in to your container instance and run the following command: sudo docker version --format '{{.Server.APIVersion}}'

      Attempts to modify the collection returned by this method will result in an UnsupportedOperationException.

      This method will never return null. If you would like to know whether the service returned this field (so that you can differentiate between null and empty), you can use the hasDockerLabels() method.

      Returns:
      A key/value map of labels to add to the container. This parameter maps to Labels in the docker container create command and the --label option to docker run. This parameter requires version 1.18 of the Docker Remote API or greater on your container instance. To check the Docker Remote API version on your container instance, log in to your container instance and run the following command: sudo docker version --format '{{.Server.APIVersion}}'

    • hasUlimits

      public final boolean hasUlimits()
      For responses, this returns true if the service returned a value for the Ulimits property. This DOES NOT check that the value is non-empty (for which, you should check the isEmpty() method on the property). This is useful because the SDK will never return a null collection or map, but you may need to differentiate between the service returning nothing (or null) and the service returning an empty collection or map. For requests, this returns true if a value for the property was specified in the request builder, and false if a value was not specified.

    • ulimits

      public final List<Ulimit> ulimits()

      A list of ulimits to set in the container. If a ulimit value is specified in a task definition, it overrides the default values set by Docker. This parameter maps to Ulimits in the docker container create command and the --ulimit option to docker run. Valid naming values are displayed in the Ulimit data type.

      Amazon ECS tasks hosted on Fargate use the default resource limit values set by the operating system with the exception of the nofile resource limit parameter which Fargate overrides. The nofile resource limit sets a restriction on the number of open files that a container can use. The default nofile soft limit is 65535 and the default hard limit is 65535.

      This parameter requires version 1.18 of the Docker Remote API or greater on your container instance. To check the Docker Remote API version on your container instance, log in to your container instance and run the following command: sudo docker version --format '{{.Server.APIVersion}}'

      This parameter is not supported for Windows containers.

      Attempts to modify the collection returned by this method will result in an UnsupportedOperationException.

      This method will never return null. If you would like to know whether the service returned this field (so that you can differentiate between null and empty), you can use the hasUlimits() method.

      Returns:
      A list of ulimits to set in the container. If a ulimit value is specified in a task definition, it overrides the default values set by Docker. This parameter maps to Ulimits in the docker container create command and the --ulimit option to docker run. Valid naming values are displayed in the Ulimit data type.

      Amazon ECS tasks hosted on Fargate use the default resource limit values set by the operating system with the exception of the nofile resource limit parameter which Fargate overrides. The nofile resource limit sets a restriction on the number of open files that a container can use. The default nofile soft limit is 65535 and the default hard limit is 65535.

      This parameter requires version 1.18 of the Docker Remote API or greater on your container instance. To check the Docker Remote API version on your container instance, log in to your container instance and run the following command: sudo docker version --format '{{.Server.APIVersion}}'

      This parameter is not supported for Windows containers.

    • logConfiguration

      public final LogConfiguration logConfiguration()

      The log configuration specification for the container.

      This parameter maps to LogConfig in the docker container create command and the --log-driver option to docker run. By default, containers use the same logging driver that the Docker daemon uses. However the container can use a different logging driver than the Docker daemon by specifying a log driver with this parameter in the container definition. To use a different logging driver for a container, the log system must be configured properly on the container instance (or on a different log server for remote logging options).

      Amazon ECS currently supports a subset of the logging drivers available to the Docker daemon (shown in the LogConfiguration data type). Additional log drivers may be available in future releases of the Amazon ECS container agent.

      This parameter requires version 1.18 of the Docker Remote API or greater on your container instance. To check the Docker Remote API version on your container instance, log in to your container instance and run the following command: sudo docker version --format '{{.Server.APIVersion}}'

      The Amazon ECS container agent running on a container instance must register the logging drivers available on that instance with the ECS_AVAILABLE_LOGGING_DRIVERS environment variable before containers placed on that instance can use these log configuration options. For more information, see Amazon ECS Container Agent Configuration in the Amazon Elastic Container Service Developer Guide.

      Returns:
      The log configuration specification for the container.

      This parameter maps to LogConfig in the docker container create command and the --log-driver option to docker run. By default, containers use the same logging driver that the Docker daemon uses. However the container can use a different logging driver than the Docker daemon by specifying a log driver with this parameter in the container definition. To use a different logging driver for a container, the log system must be configured properly on the container instance (or on a different log server for remote logging options).

      Amazon ECS currently supports a subset of the logging drivers available to the Docker daemon (shown in the LogConfiguration data type). Additional log drivers may be available in future releases of the Amazon ECS container agent.

      This parameter requires version 1.18 of the Docker Remote API or greater on your container instance. To check the Docker Remote API version on your container instance, log in to your container instance and run the following command: sudo docker version --format '{{.Server.APIVersion}}'

      The Amazon ECS container agent running on a container instance must register the logging drivers available on that instance with the ECS_AVAILABLE_LOGGING_DRIVERS environment variable before containers placed on that instance can use these log configuration options. For more information, see Amazon ECS Container Agent Configuration in the Amazon Elastic Container Service Developer Guide.

    • healthCheck

      public final HealthCheck healthCheck()

      The container health check command and associated configuration parameters for the container. This parameter maps to HealthCheck in the docker container create command and the HEALTHCHECK parameter of docker run.

      Returns:
      The container health check command and associated configuration parameters for the container. This parameter maps to HealthCheck in the docker container create command and the HEALTHCHECK parameter of docker run.

    • hasSystemControls

      public final boolean hasSystemControls()
      For responses, this returns true if the service returned a value for the SystemControls property. This DOES NOT check that the value is non-empty (for which, you should check the isEmpty() method on the property). This is useful because the SDK will never return a null collection or map, but you may need to differentiate between the service returning nothing (or null) and the service returning an empty collection or map. For requests, this returns true if a value for the property was specified in the request builder, and false if a value was not specified.

    • systemControls

      public final List<SystemControl> systemControls()

      A list of namespaced kernel parameters to set in the container. This parameter maps to Sysctls in the docker container create command and the --sysctl option to docker run. For example, you can configure net.ipv4.tcp_keepalive_time setting to maintain longer lived connections.

      Attempts to modify the collection returned by this method will result in an UnsupportedOperationException.

      This method will never return null. If you would like to know whether the service returned this field (so that you can differentiate between null and empty), you can use the hasSystemControls() method.

      Returns:
      A list of namespaced kernel parameters to set in the container. This parameter maps to Sysctls in the docker container create command and the --sysctl option to docker run. For example, you can configure net.ipv4.tcp_keepalive_time setting to maintain longer lived connections.

    • hasResourceRequirements

      public final boolean hasResourceRequirements()
      For responses, this returns true if the service returned a value for the ResourceRequirements property. This DOES NOT check that the value is non-empty (for which, you should check the isEmpty() method on the property). This is useful because the SDK will never return a null collection or map, but you may need to differentiate between the service returning nothing (or null) and the service returning an empty collection or map. For requests, this returns true if a value for the property was specified in the request builder, and false if a value was not specified.

    • resourceRequirements

      public final List<ResourceRequirement> resourceRequirements()

      The type and amount of a resource to assign to a container. The only supported resource is a GPU.

      Attempts to modify the collection returned by this method will result in an UnsupportedOperationException.

      This method will never return null. If you would like to know whether the service returned this field (so that you can differentiate between null and empty), you can use the hasResourceRequirements() method.

      Returns:
      The type and amount of a resource to assign to a container. The only supported resource is a GPU.

    • firelensConfiguration

      public final FirelensConfiguration firelensConfiguration()

      The FireLens configuration for the container. This is used to specify and configure a log router for container logs. For more information, see Custom Log Routing in the Amazon Elastic Container Service Developer Guide.

      Returns:
      The FireLens configuration for the container. This is used to specify and configure a log router for container logs. For more information, see Custom Log Routing in the Amazon Elastic Container Service Developer Guide.

    • hasCredentialSpecs

      public final boolean hasCredentialSpecs()
      For responses, this returns true if the service returned a value for the CredentialSpecs property. This DOES NOT check that the value is non-empty (for which, you should check the isEmpty() method on the property). This is useful because the SDK will never return a null collection or map, but you may need to differentiate between the service returning nothing (or null) and the service returning an empty collection or map. For requests, this returns true if a value for the property was specified in the request builder, and false if a value was not specified.

    • credentialSpecs

      public final List<String> credentialSpecs()

      A list of ARNs in SSM or Amazon S3 to a credential spec (CredSpec) file that configures the container for Active Directory authentication. We recommend that you use this parameter instead of the dockerSecurityOptions. The maximum number of ARNs is 1.

      There are two formats for each ARN.

      credentialspecdomainless:MyARN

      You use credentialspecdomainless:MyARN to provide a CredSpec with an additional section for a secret in Secrets Manager. You provide the login credentials to the domain in the secret.

      Each task that runs on any container instance can join different domains.

      You can use this format without joining the container instance to a domain.

      credentialspec:MyARN

      You use credentialspec:MyARN to provide a CredSpec for a single domain.

      You must join the container instance to the domain before you start any tasks that use this task definition.

      In both formats, replace MyARN with the ARN in SSM or Amazon S3.

      If you provide a credentialspecdomainless:MyARN, the credspec must provide a ARN in Secrets Manager for a secret containing the username, password, and the domain to connect to. For better security, the instance isn't joined to the domain for domainless authentication. Other applications on the instance can't use the domainless credentials. You can use this parameter to run tasks on the same instance, even it the tasks need to join different domains. For more information, see Using gMSAs for Windows Containers and Using gMSAs for Linux Containers.

      Attempts to modify the collection returned by this method will result in an UnsupportedOperationException.

      This method will never return null. If you would like to know whether the service returned this field (so that you can differentiate between null and empty), you can use the hasCredentialSpecs() method.

      Returns:
      A list of ARNs in SSM or Amazon S3 to a credential spec (CredSpec) file that configures the container for Active Directory authentication. We recommend that you use this parameter instead of the dockerSecurityOptions. The maximum number of ARNs is 1.

      There are two formats for each ARN.

      credentialspecdomainless:MyARN

      You use credentialspecdomainless:MyARN to provide a CredSpec with an additional section for a secret in Secrets Manager. You provide the login credentials to the domain in the secret.

      Each task that runs on any container instance can join different domains.

      You can use this format without joining the container instance to a domain.

      credentialspec:MyARN

      You use credentialspec:MyARN to provide a CredSpec for a single domain.

      You must join the container instance to the domain before you start any tasks that use this task definition.

      In both formats, replace MyARN with the ARN in SSM or Amazon S3.

      If you provide a credentialspecdomainless:MyARN, the credspec must provide a ARN in Secrets Manager for a secret containing the username, password, and the domain to connect to. For better security, the instance isn't joined to the domain for domainless authentication. Other applications on the instance can't use the domainless credentials. You can use this parameter to run tasks on the same instance, even it the tasks need to join different domains. For more information, see Using gMSAs for Windows Containers and Using gMSAs for Linux Containers.

    • toBuilder

      public ContainerDefinition.Builder toBuilder()
      Description copied from interface: ToCopyableBuilder
      Take this object and create a builder that contains all of the current property values of this object.
      Specified by:
      toBuilder in interface ToCopyableBuilder<ContainerDefinition.Builder,ContainerDefinition>
      Returns:
      a builder for type T

    • builder

      public static ContainerDefinition.Builder builder()

    • serializableBuilderClass

      public static Class<? extends ContainerDefinition.Builder> serializableBuilderClass()

    • hashCode

      public final int hashCode()
      Overrides:
      hashCode in class Object

    • equals

      public final boolean equals(Object obj)
      Overrides:
      equals in class Object

    • equalsBySdkFields

      public final boolean equalsBySdkFields(Object obj)
      Description copied from interface: SdkPojo
      Indicates whether some other object is "equal to" this one by SDK fields. An SDK field is a modeled, non-inherited field in an SdkPojo class, and is generated based on a service model.

      If an SdkPojo class does not have any inherited fields, equalsBySdkFields and equals are essentially the same.

      Specified by:
      equalsBySdkFields in interface SdkPojo
      Parameters:
      obj - the object to be compared with
      Returns:
      true if the other object equals to this object by sdk fields, false otherwise.

    • toString

      public final String toString()
      Returns a string representation of this object. This is useful for testing and debugging. Sensitive data will be redacted from this string using a placeholder value.
      Overrides:
      toString in class Object

    • getValueForField

      public final <T> Optional<T> getValueForField(String fieldName, Class<T> clazz)

    • sdkFields

      public final List<SdkField<?>> sdkFields()
      Specified by:
      sdkFields in interface SdkPojo
      Returns:
      List of SdkField in this POJO. May be empty list but should never be null.

    • sdkFieldNameToField

      public final Map<String,SdkField<?>> sdkFieldNameToField()
      Specified by:
      sdkFieldNameToField in interface SdkPojo
      Returns:
      The mapping between the field name and its corresponding field.