pulumi-gcp-kotlin/com.pulumi.gcp.compute.kotlin/DiskArgs

DiskArgs

data class DiskArgs(val accessMode: Output<String>? = null, val asyncPrimaryDisk: Output<DiskAsyncPrimaryDiskArgs>? = null, val description: Output<String>? = null, val diskEncryptionKey: Output<DiskDiskEncryptionKeyArgs>? = null, val enableConfidentialCompute: Output<Boolean>? = null, val guestOsFeatures: Output<List<DiskGuestOsFeatureArgs>>? = null, val image: Output<String>? = null, val interface: Output<String>? = null, val labels: Output<Map<String, String>>? = null, val licenses: Output<List<String>>? = null, val multiWriter: Output<Boolean>? = null, val name: Output<String>? = null, val physicalBlockSizeBytes: Output<Int>? = null, val project: Output<String>? = null, val provisionedIops: Output<Int>? = null, val provisionedThroughput: Output<Int>? = null, val resourcePolicies: Output<List<String>>? = null, val size: Output<Int>? = null, val snapshot: Output<String>? = null, val sourceDisk: Output<String>? = null, val sourceImageEncryptionKey: Output<DiskSourceImageEncryptionKeyArgs>? = null, val sourceSnapshotEncryptionKey: Output<DiskSourceSnapshotEncryptionKeyArgs>? = null, val storagePool: Output<String>? = null, val type: Output<String>? = null, val zone: Output<String>? = null) : ConvertibleToJava<DiskArgs>

Persistent disks are durable storage devices that function similarly to the physical disks in a desktop or a server. Compute Engine manages the hardware behind these devices to ensure data redundancy and optimize performance for you. Persistent disks are available as either standard hard disk drives (HDD) or solid-state drives (SSD). Persistent disks are located independently from your virtual machine instances, so you can detach or move persistent disks to keep your data even after you delete your instances. Persistent disk performance scales automatically with size, so you can resize your existing persistent disks or add more persistent disks to an instance to meet your performance and storage space requirements. Add a persistent disk to your instance when you need reliable and affordable storage with consistent performance characteristics. To get more information about Disk, see:

API documentation
How-to Guides

Adding a persistent disk

Example Usage

Disk Basic

import * as pulumi from "@pulumi/pulumi";
import * as gcp from "@pulumi/gcp";
const _default = new gcp.compute.Disk("default", {
    name: "test-disk",
    type: "pd-ssd",
    zone: "us-central1-a",
    image: "debian-11-bullseye-v20220719",
    labels: {
        environment: "dev",
    },
    physicalBlockSizeBytes: 4096,
});

import pulumi
import pulumi_gcp as gcp
default = gcp.compute.Disk("default",
    name="test-disk",
    type="pd-ssd",
    zone="us-central1-a",
    image="debian-11-bullseye-v20220719",
    labels={
        "environment": "dev",
    },
    physical_block_size_bytes=4096)

using System.Collections.Generic;
using System.Linq;
using Pulumi;
using Gcp = Pulumi.Gcp;
return await Deployment.RunAsync(() =>
{
    var @default = new Gcp.Compute.Disk("default", new()
    {
        Name = "test-disk",
        Type = "pd-ssd",
        Zone = "us-central1-a",
        Image = "debian-11-bullseye-v20220719",
        Labels =
        {
            { "environment", "dev" },
        },
        PhysicalBlockSizeBytes = 4096,
    });
});

package main
import (
	"github.com/pulumi/pulumi-gcp/sdk/v7/go/gcp/compute"
	"github.com/pulumi/pulumi/sdk/v3/go/pulumi"
)
func main() {
	pulumi.Run(func(ctx *pulumi.Context) error {
		_, err := compute.NewDisk(ctx, "default", &compute.DiskArgs{
			Name:  pulumi.String("test-disk"),
			Type:  pulumi.String("pd-ssd"),
			Zone:  pulumi.String("us-central1-a"),
			Image: pulumi.String("debian-11-bullseye-v20220719"),
			Labels: pulumi.StringMap{
				"environment": pulumi.String("dev"),
			},
			PhysicalBlockSizeBytes: pulumi.Int(4096),
		})
		if err != nil {
			return err
		}
		return nil
	})
}

package generated_program;
import com.pulumi.Context;
import com.pulumi.Pulumi;
import com.pulumi.core.Output;
import com.pulumi.gcp.compute.Disk;
import com.pulumi.gcp.compute.DiskArgs;
import java.util.List;
import java.util.ArrayList;
import java.util.Map;
import java.io.File;
import java.nio.file.Files;
import java.nio.file.Paths;
public class App {
    public static void main(String[] args) {
        Pulumi.run(App::stack);
    }
    public static void stack(Context ctx) {
        var default_ = new Disk("default", DiskArgs.builder()
            .name("test-disk")
            .type("pd-ssd")
            .zone("us-central1-a")
            .image("debian-11-bullseye-v20220719")
            .labels(Map.of("environment", "dev"))
            .physicalBlockSizeBytes(4096)
            .build());
    }
}

resources:
  default:
    type: gcp:compute:Disk
    properties:
      name: test-disk
      type: pd-ssd
      zone: us-central1-a
      image: debian-11-bullseye-v20220719
      labels:
        environment: dev
      physicalBlockSizeBytes: 4096

Disk Async

import * as pulumi from "@pulumi/pulumi";
import * as gcp from "@pulumi/gcp";
const primary = new gcp.compute.Disk("primary", {
    name: "async-test-disk",
    type: "pd-ssd",
    zone: "us-central1-a",
    physicalBlockSizeBytes: 4096,
});
const secondary = new gcp.compute.Disk("secondary", {
    name: "async-secondary-test-disk",
    type: "pd-ssd",
    zone: "us-east1-c",
    asyncPrimaryDisk: {
        disk: primary.id,
    },
    physicalBlockSizeBytes: 4096,
});

import pulumi
import pulumi_gcp as gcp
primary = gcp.compute.Disk("primary",
    name="async-test-disk",
    type="pd-ssd",
    zone="us-central1-a",
    physical_block_size_bytes=4096)
secondary = gcp.compute.Disk("secondary",
    name="async-secondary-test-disk",
    type="pd-ssd",
    zone="us-east1-c",
    async_primary_disk={
        "disk": primary.id,
    },
    physical_block_size_bytes=4096)

using System.Collections.Generic;
using System.Linq;
using Pulumi;
using Gcp = Pulumi.Gcp;
return await Deployment.RunAsync(() =>
{
    var primary = new Gcp.Compute.Disk("primary", new()
    {
        Name = "async-test-disk",
        Type = "pd-ssd",
        Zone = "us-central1-a",
        PhysicalBlockSizeBytes = 4096,
    });
    var secondary = new Gcp.Compute.Disk("secondary", new()
    {
        Name = "async-secondary-test-disk",
        Type = "pd-ssd",
        Zone = "us-east1-c",
        AsyncPrimaryDisk = new Gcp.Compute.Inputs.DiskAsyncPrimaryDiskArgs
        {
            Disk = primary.Id,
        },
        PhysicalBlockSizeBytes = 4096,
    });
});

package main
import (
	"github.com/pulumi/pulumi-gcp/sdk/v7/go/gcp/compute"
	"github.com/pulumi/pulumi/sdk/v3/go/pulumi"
)
func main() {
	pulumi.Run(func(ctx *pulumi.Context) error {
		primary, err := compute.NewDisk(ctx, "primary", &compute.DiskArgs{
			Name:                   pulumi.String("async-test-disk"),
			Type:                   pulumi.String("pd-ssd"),
			Zone:                   pulumi.String("us-central1-a"),
			PhysicalBlockSizeBytes: pulumi.Int(4096),
		})
		if err != nil {
			return err
		}
		_, err = compute.NewDisk(ctx, "secondary", &compute.DiskArgs{
			Name: pulumi.String("async-secondary-test-disk"),
			Type: pulumi.String("pd-ssd"),
			Zone: pulumi.String("us-east1-c"),
			AsyncPrimaryDisk: &compute.DiskAsyncPrimaryDiskArgs{
				Disk: primary.ID(),
			},
			PhysicalBlockSizeBytes: pulumi.Int(4096),
		})
		if err != nil {
			return err
		}
		return nil
	})
}

package generated_program;
import com.pulumi.Context;
import com.pulumi.Pulumi;
import com.pulumi.core.Output;
import com.pulumi.gcp.compute.Disk;
import com.pulumi.gcp.compute.DiskArgs;
import com.pulumi.gcp.compute.inputs.DiskAsyncPrimaryDiskArgs;
import java.util.List;
import java.util.ArrayList;
import java.util.Map;
import java.io.File;
import java.nio.file.Files;
import java.nio.file.Paths;
public class App {
    public static void main(String[] args) {
        Pulumi.run(App::stack);
    }
    public static void stack(Context ctx) {
        var primary = new Disk("primary", DiskArgs.builder()
            .name("async-test-disk")
            .type("pd-ssd")
            .zone("us-central1-a")
            .physicalBlockSizeBytes(4096)
            .build());
        var secondary = new Disk("secondary", DiskArgs.builder()
            .name("async-secondary-test-disk")
            .type("pd-ssd")
            .zone("us-east1-c")
            .asyncPrimaryDisk(DiskAsyncPrimaryDiskArgs.builder()
                .disk(primary.id())
                .build())
            .physicalBlockSizeBytes(4096)
            .build());
    }
}

resources:
  primary:
    type: gcp:compute:Disk
    properties:
      name: async-test-disk
      type: pd-ssd
      zone: us-central1-a
      physicalBlockSizeBytes: 4096
  secondary:
    type: gcp:compute:Disk
    properties:
      name: async-secondary-test-disk
      type: pd-ssd
      zone: us-east1-c
      asyncPrimaryDisk:
        disk: ${primary.id}
      physicalBlockSizeBytes: 4096

Disk Features

import * as pulumi from "@pulumi/pulumi";
import * as gcp from "@pulumi/gcp";
const _default = new gcp.compute.Disk("default", {
    name: "test-disk-features",
    type: "pd-ssd",
    zone: "us-central1-a",
    labels: {
        environment: "dev",
    },
    guestOsFeatures: [
        {
            type: "SECURE_BOOT",
        },
        {
            type: "MULTI_IP_SUBNET",
        },
        {
            type: "WINDOWS",
        },
    ],
    licenses: ["https://www&#46;googleapis&#46;com/compute/v1/projects/windows-cloud/global/licenses/windows-server-core"],
    physicalBlockSizeBytes: 4096,
});

import pulumi
import pulumi_gcp as gcp
default = gcp.compute.Disk("default",
    name="test-disk-features",
    type="pd-ssd",
    zone="us-central1-a",
    labels={
        "environment": "dev",
    },
    guest_os_features=[
        {
            "type": "SECURE_BOOT",
        },
        {
            "type": "MULTI_IP_SUBNET",
        },
        {
            "type": "WINDOWS",
        },
    ],
    licenses=["https://www&#46;googleapis&#46;com/compute/v1/projects/windows-cloud/global/licenses/windows-server-core"],
    physical_block_size_bytes=4096)

using System.Collections.Generic;
using System.Linq;
using Pulumi;
using Gcp = Pulumi.Gcp;
return await Deployment.RunAsync(() =>
{
    var @default = new Gcp.Compute.Disk("default", new()
    {
        Name = "test-disk-features",
        Type = "pd-ssd",
        Zone = "us-central1-a",
        Labels =
        {
            { "environment", "dev" },
        },
        GuestOsFeatures = new[]
        {
            new Gcp.Compute.Inputs.DiskGuestOsFeatureArgs
            {
                Type = "SECURE_BOOT",
            },
            new Gcp.Compute.Inputs.DiskGuestOsFeatureArgs
            {
                Type = "MULTI_IP_SUBNET",
            },
            new Gcp.Compute.Inputs.DiskGuestOsFeatureArgs
            {
                Type = "WINDOWS",
            },
        },
        Licenses = new[]
        {
            "https://www.googleapis.com/compute/v1/projects/windows-cloud/global/licenses/windows-server-core",
        },
        PhysicalBlockSizeBytes = 4096,
    });
});

package main
import (
	"github.com/pulumi/pulumi-gcp/sdk/v7/go/gcp/compute"
	"github.com/pulumi/pulumi/sdk/v3/go/pulumi"
)
func main() {
	pulumi.Run(func(ctx *pulumi.Context) error {
		_, err := compute.NewDisk(ctx, "default", &compute.DiskArgs{
			Name: pulumi.String("test-disk-features"),
			Type: pulumi.String("pd-ssd"),
			Zone: pulumi.String("us-central1-a"),
			Labels: pulumi.StringMap{
				"environment": pulumi.String("dev"),
			},
			GuestOsFeatures: compute.DiskGuestOsFeatureArray{
				&compute.DiskGuestOsFeatureArgs{
					Type: pulumi.String("SECURE_BOOT"),
				},
				&compute.DiskGuestOsFeatureArgs{
					Type: pulumi.String("MULTI_IP_SUBNET"),
				},
				&compute.DiskGuestOsFeatureArgs{
					Type: pulumi.String("WINDOWS"),
				},
			},
			Licenses: pulumi.StringArray{
				pulumi.String("https://www.googleapis.com/compute/v1/projects/windows-cloud/global/licenses/windows-server-core"),
			},
			PhysicalBlockSizeBytes: pulumi.Int(4096),
		})
		if err != nil {
			return err
		}
		return nil
	})
}

package generated_program;
import com.pulumi.Context;
import com.pulumi.Pulumi;
import com.pulumi.core.Output;
import com.pulumi.gcp.compute.Disk;
import com.pulumi.gcp.compute.DiskArgs;
import com.pulumi.gcp.compute.inputs.DiskGuestOsFeatureArgs;
import java.util.List;
import java.util.ArrayList;
import java.util.Map;
import java.io.File;
import java.nio.file.Files;
import java.nio.file.Paths;
public class App {
    public static void main(String[] args) {
        Pulumi.run(App::stack);
    }
    public static void stack(Context ctx) {
        var default_ = new Disk("default", DiskArgs.builder()
            .name("test-disk-features")
            .type("pd-ssd")
            .zone("us-central1-a")
            .labels(Map.of("environment", "dev"))
            .guestOsFeatures(
                DiskGuestOsFeatureArgs.builder()
                    .type("SECURE_BOOT")
                    .build(),
                DiskGuestOsFeatureArgs.builder()
                    .type("MULTI_IP_SUBNET")
                    .build(),
                DiskGuestOsFeatureArgs.builder()
                    .type("WINDOWS")
                    .build())
            .licenses("https://www.googleapis.com/compute/v1/projects/windows-cloud/global/licenses/windows-server-core")
            .physicalBlockSizeBytes(4096)
            .build());
    }
}

resources:
  default:
    type: gcp:compute:Disk
    properties:
      name: test-disk-features
      type: pd-ssd
      zone: us-central1-a
      labels:
        environment: dev
      guestOsFeatures:
        - type: SECURE_BOOT
        - type: MULTI_IP_SUBNET
        - type: WINDOWS
      licenses:
        - https://www.googleapis.com/compute/v1/projects/windows-cloud/global/licenses/windows-server-core
      physicalBlockSizeBytes: 4096

Import

Disk can be imported using any of these accepted formats:

projects/{{project}}/zones/{{zone}}/disks/{{name}}
{{project}}/{{zone}}/{{name}}
{{zone}}/{{name}}
{{name}} When using the pulumi import command, Disk can be imported using one of the formats above. For example:

$ pulumi import gcp:compute/disk:Disk default projects/{{project}}/zones/{{zone}}/disks/{{name}}

$ pulumi import gcp:compute/disk:Disk default {{project}}/{{zone}}/{{name}}

$ pulumi import gcp:compute/disk:Disk default {{zone}}/{{name}}

$ pulumi import gcp:compute/disk:Disk default {{name}}

Constructors

DiskArgs

constructor(accessMode: Output<String>? = null, asyncPrimaryDisk: Output<DiskAsyncPrimaryDiskArgs>? = null, description: Output<String>? = null, diskEncryptionKey: Output<DiskDiskEncryptionKeyArgs>? = null, enableConfidentialCompute: Output<Boolean>? = null, guestOsFeatures: Output<List<DiskGuestOsFeatureArgs>>? = null, image: Output<String>? = null, interface: Output<String>? = null, labels: Output<Map<String, String>>? = null, licenses: Output<List<String>>? = null, multiWriter: Output<Boolean>? = null, name: Output<String>? = null, physicalBlockSizeBytes: Output<Int>? = null, project: Output<String>? = null, provisionedIops: Output<Int>? = null, provisionedThroughput: Output<Int>? = null, resourcePolicies: Output<List<String>>? = null, size: Output<Int>? = null, snapshot: Output<String>? = null, sourceDisk: Output<String>? = null, sourceImageEncryptionKey: Output<DiskSourceImageEncryptionKeyArgs>? = null, sourceSnapshotEncryptionKey: Output<DiskSourceSnapshotEncryptionKeyArgs>? = null, storagePool: Output<String>? = null, type: Output<String>? = null, zone: Output<String>? = null)

Properties

accessMode

val accessMode: Output<String>? = null

The accessMode of the disk. For example:

asyncPrimaryDisk

val asyncPrimaryDisk: Output<DiskAsyncPrimaryDiskArgs>? = null

A nested object resource Structure is documented below.

description

val description: Output<String>? = null

An optional description of this resource. Provide this property when you create the resource.

diskEncryptionKey

val diskEncryptionKey: Output<DiskDiskEncryptionKeyArgs>? = null

Encrypts the disk using a customer-supplied encryption key. After you encrypt a disk with a customer-supplied key, you must provide the same key if you use the disk later (e.g. to create a disk snapshot or an image, or to attach the disk to a virtual machine). Customer-supplied encryption keys do not protect access to metadata of the disk. If you do not provide an encryption key when creating the disk, then the disk will be encrypted using an automatically generated key and you do not need to provide a key to use the disk later. Structure is documented below.

enableConfidentialCompute

val enableConfidentialCompute: Output<Boolean>? = null

Whether this disk is using confidential compute mode. Note: Only supported on hyperdisk skus, disk_encryption_key is required when setting to true

guestOsFeatures

val guestOsFeatures: Output<List<DiskGuestOsFeatureArgs>>? = null

A list of features to enable on the guest operating system. Applicable only for bootable disks. Structure is documented below.

image

val image: Output<String>? = null

The image from which to initialize this disk. This can be one of: the image's self_link, projects/{project}/global/images/{image}, projects/{project}/global/images/family/{family}, global/images/{image}, global/images/family/{family}, family/{family}, {project}/{family}, {project}/{image}, {family}, or {image}. If referred by family, the images names must include the family name. If they don't, use the gcp.compute.Image data source. For instance, the image centos-6-v20180104 includes its family name centos-6. These images can be referred by family name here.

interface

val ~~interface~~: Output<String>? = null

Specifies the disk interface to use for attaching this disk, which is either SCSI or NVME. The default is SCSI.

labels

val labels: Output<Map<String, String>>? = null

Labels to apply to this disk. A list of key->value pairs. Note: This field is non-authoritative, and will only manage the labels present in your configuration. Please refer to the field effective_labels for all of the labels present on the resource.

licenses

val licenses: Output<List<String>>? = null

Any applicable license URI.

multiWriter

val multiWriter: Output<Boolean>? = null

Indicates whether or not the disk can be read/write attached to more than one instance.

name

val name: Output<String>? = null

Name of the resource. Provided by the client when the resource is created. The name must be 1-63 characters long, and comply with RFC1035. Specifically, the name must be 1-63 characters long and match the regular expression a-z? which means the first character must be a lowercase letter, and all following characters must be a dash, lowercase letter, or digit, except the last character, which cannot be a dash.

physicalBlockSizeBytes

val physicalBlockSizeBytes: Output<Int>? = null

Physical block size of the persistent disk, in bytes. If not present in a request, a default value is used. Currently supported sizes are 4096 and 16384, other sizes may be added in the future. If an unsupported value is requested, the error message will list the supported values for the caller's project.

project

val project: Output<String>? = null

The ID of the project in which the resource belongs. If it is not provided, the provider project is used.

provisionedIops

val provisionedIops: Output<Int>? = null

Indicates how many IOPS must be provisioned for the disk. Note: Updating currently is only supported by hyperdisk skus without the need to delete and recreate the disk, hyperdisk allows for an update of IOPS every 4 hours. To update your hyperdisk more frequently, you'll need to manually delete and recreate it

provisionedThroughput

val provisionedThroughput: Output<Int>? = null

Indicates how much Throughput must be provisioned for the disk. Note: Updating currently is only supported by hyperdisk skus without the need to delete and recreate the disk, hyperdisk allows for an update of Throughput every 4 hours. To update your hyperdisk more frequently, you'll need to manually delete and recreate it

resourcePolicies

val resourcePolicies: Output<List<String>>? = null

Resource policies applied to this disk for automatic snapshot creations. ~>NOTE This value does not support updating the resource policy, as resource policies can not be updated more than one at a time. Use gcp.compute.DiskResourcePolicyAttachment to allow for updating the resource policy attached to the disk.

size

val size: Output<Int>? = null

Size of the persistent disk, specified in GB. You can specify this field when creating a persistent disk using the image or snapshot parameter, or specify it alone to create an empty persistent disk. If you specify this field along with image or snapshot, the value must not be less than the size of the image or the size of the snapshot. ~>NOTE If you change the size, the provider updates the disk size if upsizing is detected but recreates the disk if downsizing is requested. You can add lifecycle.prevent_destroy in the config to prevent destroying and recreating.

snapshot

val snapshot: Output<String>? = null

The source snapshot used to create this disk. You can provide this as a partial or full URL to the resource. If the snapshot is in another project than this disk, you must supply a full URL. For example, the following are valid values:

sourceDisk

val sourceDisk: Output<String>? = null

The source disk used to create this disk. You can provide this as a partial or full URL to the resource. For example, the following are valid values:

sourceImageEncryptionKey

val sourceImageEncryptionKey: Output<DiskSourceImageEncryptionKeyArgs>? = null

The customer-supplied encryption key of the source image. Required if the source image is protected by a customer-supplied encryption key. Structure is documented below.

sourceSnapshotEncryptionKey

val sourceSnapshotEncryptionKey: Output<DiskSourceSnapshotEncryptionKeyArgs>? = null

The customer-supplied encryption key of the source snapshot. Required if the source snapshot is protected by a customer-supplied encryption key. Structure is documented below.

storagePool

val storagePool: Output<String>? = null

The URL of the storage pool in which the new disk is created. For example:

type

val type: Output<String>? = null

URL of the disk type resource describing which disk type to use to create the disk. Provide this when creating the disk.

zone

val zone: Output<String>? = null

A reference to the zone where the disk resides.

Functions

toJava

open override fun toJava(): DiskArgs