커스텀 머신 유형으로 VM 만들기


Compute Engine은 VM 인스턴스를 만들 때 사용할 수 있는 사전 정의된 머신 유형을 제공합니다. 사전 정의된 머신 유형에는 vCPU 수 및 메모리 양이 미리 설정되어 있으며 설정된 요금으로 요금이 청구됩니다. 사전 정의된 VM이 요구사항을 충족하지 못하는 경우에는 커스텀 가상화된 하드웨어 설정으로 VM 인스턴스를 만들면 됩니다. 커스텀 머신 유형을 사용하면 특히 vCPU 수와 메모리 양이 맞춤설정된 VM 인스턴스를 만들 수 있습니다. 커스텀 머신 유형은 범용 머신 계열의 N 및 E 머신 시리즈에서만 사용할 수 있습니다. C 및 Tau 머신 시리즈에는 커스텀 머신 유형을 사용할 수 없습니다. N4, N2, N2D, E2 또는 N1 머신 유형에서 커스텀 VM을 만들 수 있습니다.

커스텀 VM은 다음과 같은 시나리오에 적합합니다.

  • 사전 정의된 VM 유형에 적합하지 않은 워크로드
  • 추가 처리 능력이나 메모리가 필요하지만 다음 수준 머신 유형에서 제공되는 모든 업그레이드는 필요하지 않은 워크로드

시작하기 전에

  • 머신 계열 문서 읽기
  • 아직 인증을 설정하지 않았다면 설정합니다. 인증은 Google Cloud 서비스 및 API에 액세스하기 위해 ID를 확인하는 프로세스입니다. 로컬 개발 환경에서 코드 또는 샘플을 실행하려면 다음 옵션 중 하나를 선택하여 Compute Engine에 인증하면 됩니다.

    Select the tab for how you plan to use the samples on this page:

    Console

    When you use the Google Cloud console to access Google Cloud services and APIs, you don't need to set up authentication.

    gcloud

    1. Install the Google Cloud CLI, then initialize it by running the following command:

      gcloud init
    2. Set a default region and zone.
    3. Terraform

      로컬 개발 환경에서 이 페이지의 Terraform 샘플을 사용하려면 gcloud CLI를 설치 및 초기화한 다음 사용자 인증 정보로 애플리케이션 기본 사용자 인증 정보를 설정하세요.

      1. Install the Google Cloud CLI.
      2. To initialize the gcloud CLI, run the following command:

        gcloud init
      3. If you're using a local shell, then create local authentication credentials for your user account:

        gcloud auth application-default login

        You don't need to do this if you're using Cloud Shell.

      자세한 내용은 다음을 참조하세요: Set up authentication for a local development environment.

      Go

      로컬 개발 환경에서 이 페이지의 Go 샘플을 사용하려면 gcloud CLI를 설치 및 초기화한 다음 사용자 인증 정보로 애플리케이션 기본 사용자 인증 정보를 설정하세요.

      1. Install the Google Cloud CLI.
      2. To initialize the gcloud CLI, run the following command:

        gcloud init
      3. If you're using a local shell, then create local authentication credentials for your user account:

        gcloud auth application-default login

        You don't need to do this if you're using Cloud Shell.

      자세한 내용은 다음을 참조하세요: Set up authentication for a local development environment.

      Java

      로컬 개발 환경에서 이 페이지의 Java 샘플을 사용하려면 gcloud CLI를 설치 및 초기화한 다음 사용자 인증 정보로 애플리케이션 기본 사용자 인증 정보를 설정하세요.

      1. Install the Google Cloud CLI.
      2. To initialize the gcloud CLI, run the following command:

        gcloud init
      3. If you're using a local shell, then create local authentication credentials for your user account:

        gcloud auth application-default login

        You don't need to do this if you're using Cloud Shell.

      자세한 내용은 다음을 참조하세요: Set up authentication for a local development environment.

      Node.js

      로컬 개발 환경에서 이 페이지의 Node.js 샘플을 사용하려면 gcloud CLI를 설치 및 초기화한 다음 사용자 인증 정보로 애플리케이션 기본 사용자 인증 정보를 설정하세요.

      1. Install the Google Cloud CLI.
      2. To initialize the gcloud CLI, run the following command:

        gcloud init
      3. If you're using a local shell, then create local authentication credentials for your user account:

        gcloud auth application-default login

        You don't need to do this if you're using Cloud Shell.

      자세한 내용은 다음을 참조하세요: Set up authentication for a local development environment.

      PHP

      로컬 개발 환경에서 이 페이지의 PHP 샘플을 사용하려면 gcloud CLI를 설치 및 초기화한 다음 사용자 인증 정보로 애플리케이션 기본 사용자 인증 정보를 설정하세요.

      1. Install the Google Cloud CLI.
      2. To initialize the gcloud CLI, run the following command:

        gcloud init
      3. If you're using a local shell, then create local authentication credentials for your user account:

        gcloud auth application-default login

        You don't need to do this if you're using Cloud Shell.

      자세한 내용은 다음을 참조하세요: Set up authentication for a local development environment.

      Python

      로컬 개발 환경에서 이 페이지의 Python 샘플을 사용하려면 gcloud CLI를 설치 및 초기화한 다음 사용자 인증 정보로 애플리케이션 기본 사용자 인증 정보를 설정하세요.

      1. Install the Google Cloud CLI.
      2. To initialize the gcloud CLI, run the following command:

        gcloud init
      3. If you're using a local shell, then create local authentication credentials for your user account:

        gcloud auth application-default login

        You don't need to do this if you're using Cloud Shell.

      자세한 내용은 다음을 참조하세요: Set up authentication for a local development environment.

      REST

      로컬 개발 환경에서 이 페이지의 REST API 샘플을 사용하려면 gcloud CLI에 제공한 사용자 인증 정보를 사용합니다.

        Install the Google Cloud CLI, then initialize it by running the following command:

        gcloud init

      자세한 내용은 Google Cloud 인증 문서의 REST 사용을 위한 인증을 참고하세요.

필요한 역할

커스텀 머신 유형으로 VM을 만드는 데 필요한 권한을 얻으려면 관리자에게 프로젝트에 대한 Compute 인스턴스 관리자(v1)(roles/compute.instanceAdmin.v1) IAM 역할을 부여해 달라고 요청하세요. 역할 부여에 대한 자세한 내용은 프로젝트, 폴더, 조직에 대한 액세스 관리를 참조하세요.

이 사전 정의된 역할에는 커스텀 머신 유형으로 VM을 만드는 데 필요한 권한이 포함되어 있습니다. 필요한 정확한 권한을 보려면 필수 권한 섹션을 펼치세요.

필수 권한

커스텀 머신 유형으로 VM을 만들려면 다음 권한이 필요합니다.

  • 기존 VM에 확장 메모리 추가: VM에 대한 compute.instances.setMachineType 권한
  • 커스텀 머신 유형으로 VM 만들기:
    • 프로젝트에 대한 compute.instances.create 권한
    • 커스텀 이미지를 사용하여 VM 만들기: 이미지에 대한 compute.images.useReadOnly 권한
    • 스냅샷을 사용하여 VM 만들기: 스냅샷에 대한 compute.snapshots.useReadOnly 권한
    • 인스턴스 템플릿을 사용하여 VM 만들기: 인스턴스 템플릿에 대한 compute.instanceTemplates.useReadOnly 권한
    • VM에 기존 네트워크 할당: 프로젝트에 대한 compute.networks.use 권한
    • VM의 고정 IP 주소 지정: 프로젝트에 대한 compute.addresses.use 권한
    • 기존 네트워크 사용 시 VM에 외부 IP 주소 할당: 프로젝트에 대한 compute.networks.useExternalIp 권한
    • VM의 서브넷 지정: 프로젝트 또는 선택한 서브넷에 대한 compute.subnetworks.use 권한
    • VPC 네트워크를 사용할 때 VM에 외부 IP 주소 할당: 프로젝트 또는 선택한 서브넷에 대한 compute.subnetworks.useExternalIp 권한
    • VM에 VM 인스턴스 메타데이터 설정: 프로젝트에 대한 compute.instances.setMetadata 권한
    • VM에 태그 설정: VM에 대한 compute.instances.setTags 권한
    • VM에 라벨 설정: VM에 대한 compute.instances.setLabels 권한
    • VM에 사용할 서비스 계정 설정: VM에 대한 compute.instances.setServiceAccount 권한
    • VM의 새 디스크 만들기: 프로젝트에 대한 compute.disks.create 권한
    • 기존 디스크를 읽기 전용 또는 읽기-쓰기 모드로 연결: 디스크에 대한 compute.disks.use 권한
    • 기존 디스크를 읽기 전용 모드로 연결: 디스크에 대한 compute.disks.useReadOnly 권한

커스텀 역할이나 다른 사전 정의된 역할을 사용하여 이 권한을 부여받을 수도 있습니다.

제한사항

  • VM에 로컬 SSD 디스크가 있으면 vCPU 및 메모리 구성을 변경할 수 없습니다.
  • 확장 메모리는 커스텀 머신 유형에서만 사용할 수 있습니다. 사전 정의된 머신 유형은 지원되지 않습니다.
  • 각 머신 유형에 추가할 수 있는 최대 메모리 양이 존재합니다.
  • 메모리를 256MB 단위로 증가하게 지정해야 합니다.
  • 확장 메모리에는 약정 사용 할인이 적용되지 않습니다.
  • N4 및 N2D 머신 유형은 일부 리전 및 영역에서만 사용할 수 있습니다.

커스텀 머신 유형 가격

Google은 VM에 사용되는 vCPU 수 및 메모리 시간을 기준으로 커스텀 VM에 요금을 부과합니다. 이는 사전 정의된 머신 유형의 요금 청구 방식과 다릅니다. 커스텀 머신 유형의 주문형 가격에는 사전 정의된 머신 유형의 주문형 가격보다 5% 높은 프리미엄이 포함됩니다.

  • 커스텀 머신 유형을 사용하는 경우 vCPU당 기본 양까지는 머신 계열 커스텀 머신 유형 가격에 따라 요금이 청구됩니다. E2 커스텀 머신 및 E2 공유 코어 커스텀 머신 유형은 동일한 가격 책정 체계를 공유합니다.

  • 약정을 사용해서 커스텀 머신 유형을 실행하는 경우 Compute Engine에서 약정 가격에 5% 프리미엄을 청구합니다. Compute Engine은 이러한 커스텀 머신 유형 VM을 실행하는 약정 부분과 기간에 대해 이 프리미엄을 청구합니다.

머신 시리즈별 정보는 VM 인스턴스 가격 책정을 참조하세요.

커스텀 VM에는 다른 인스턴스와 동일한 최소 청구 시간 1분이 적용되지만 커스텀 머신 유형의 지속 사용 할인을 계산하는 방식이 다릅니다. 자세한 내용은 커스텀 VM의 지속 사용 할인을 참조하세요.

확장 메모리 가격 책정

하지만 메모리가 기본 양보다 큰 경우에는 Compute Engine에서 머신 계열 확장 커스텀 메모리 가격에 따라 확장 메모리 요금이 청구됩니다. 확장 메모리의 가격은 기본 기준보다 낮은 메모리 가격과 다릅니다.

확장 메모리 가격은 리전에 따라 다릅니다. 확장 메모리를 사용해 실행되는 인스턴스에도 다른 인스턴스와 동일한 최소 청구 시간 1분이 적용됩니다. 확장 메모리 역시 지속 사용 할인을 받을 수 있습니다.

머신 유형에 확장 메모리 추가

머신 시리즈에 따라 머신 유형마다 기본적으로 특정한 메모리 양이 적용됩니다. 하지만 일부 워크로드에서는 메모리가 부족할 수도 있습니다. 이때는 추가 비용을 지불하여 vCPU당 메모리 양을 기본 제한보다 많이 구매할 수 있습니다. 이를 확장 메모리라고 합니다.

확장 메모리를 사용하면 vCPU당 제한 없이 커스텀 머신 유형의 메모리 양을 지정할 수 있습니다. 지정된 vCPU 수를 기반으로 기본 메모리 크기를 사용하는 대신 머신 시리즈의 한도 내에서 확장 메모리 양을 지정할 수 있습니다.

머신 계열 vCPU 한도 메모리 한도
N4 80 640GB
N2 128 640GB
N2D 224 768GB
E2 32 128GB
N1 96 624GB

메모리가 더 필요하다면 VM당 총 메모리가 최대 12TB인 VM을 만들 수 있는 메모리 최적화 머신 유형 중 하나를 사용합니다.

확장 메모리 필요성 판단

일부 워크로드에서는 최적의 결과를 얻으려면 vCPU당 기본 메모리 양보다 많은 메모리가 필요합니다. MS SQL Server, MongoDB, MemcacheD/Redis와 같은 관계형 및 NoSQL 데이터베이스를 포함하여 메모리 내 고성능 분석 데이터베이스를 기반으로 하는 워크로드가 이 카테고리에 속합니다. 운영체제 및 소프트웨어 스택의 vCPU 기반 라이선스 역시 사전 정의된 머신 유형을 사용해 최적의 VM 메모리 구성을 선택하기 더욱 어렵게 만듭니다. 확장 메모리를 사용하면 VM에서 최적의 가격 대비 성능 대비 필요한 메모리를 추가할 수 있습니다.

GB 또는 MB 단위의 메모리 표현

Google Cloud 도구 및 문서에서는 머신 유형 메모리가 GB(기가바이트) 단위로 계산됩니다. 이때 1GB는 230바이트입니다. 이 측정 단위를 GiB(기비바이트)라고도 합니다. 메모리를 GB에서 MB 단위로 변환할 경우 1GB는 1,024MB입니다.

API에서 메모리는 항상 메가바이트 단위로 입력해야 합니다. Google Cloud CLI를 사용하는 경우 GB 또는 MB 단위로 VM의 총 메모리를 제공할 수 있습니다. 하지만 gcloud CLI에서는 메모리 값이 정수여야 하므로 부동 소수점 값을 제공할 수 없습니다. 예를 들어 5.75GB를 표현하려면 5.75GB를 MB 단위로 변환합니다. 이때 5.75GB는 5,888MB입니다.

커스텀 머신 유형으로 VM 만들기

커스텀 VM 인스턴스를 만들기 전에 이 머신 유형을 만들 때 따라야 할 커스텀 사양을 읽어보고 이해해야 합니다.

콘솔

  1. Google Cloud 콘솔에서 인스턴스 만들기 페이지로 이동합니다.

    인스턴스 만들기로 이동

  2. VM을 호스팅할 리전영역을 선택합니다.

  3. 머신 구성 섹션에서 범용을 선택합니다.

    1. 시리즈 목록에서 커스텀 머신을 만들 머신 시리즈를 선택합니다. N4, N2, N2D, E2, N1에서는 커스텀 머신 유형을 제공합니다.
    2. 머신 유형 섹션에서 커스텀을 선택합니다.
    3. VM 인스턴스의 vCPU 수와 메모리 양을 지정하려면 슬라이더를 드래그하거나 텍스트 상자에 값을 입력합니다. vCPU 및 메모리 수량을 변경하면 콘솔에 VM의 예상 비용이 표시됩니다.
  4. 계속해서 VM을 만듭니다.

gcloud

--machine-type 옵션과 함께 gcloud compute instances create 명령어를 사용하여 커스텀 머신을 만듭니다.

  gcloud compute instances create INSTANCE_NAME \
    --machine-type=MACHINE_TYPE-NUMBER_OF_VCPUS-AMOUNT_OF_MEMORY_MB

다음을 바꿉니다.

  • INSTANCE_NAME: 인스턴스 이름
  • MACHINE_TYPE: 머신 유형(예: N2)
  • NUMBER_OF_VCPUS: vCPU 수
  • AMOUNT_OF_MEMORY_MB: 메모리 양(MB 또는 GB)

다음은 us-central1-a 영역에서 vCPU 48개와 메모리 310GB가 있는 N2 머신 유형을 사용하는 예시입니다.

  gcloud compute instances create example-instance \
    --zone=us-central1-a --machine-type=n2-custom-48-317440

또는 커스텀 옵션인 --custom-cpu, --custom-memory, --custom-vm-type, --custom-extensions를 사용하여 커스텀 머신 유형을 지정할 수도 있습니다. 메모리 대비 vCPU의 최대 비율보다 더 많은 메모리를 지정할 수 있는 확장 메모리를 구성하려면 AMOUNT_OF_MEMORY_MB 값을 늘리고 머신 유형 이름에 -ext를 추가합니다.

  gcloud compute instances create INSTANCE_NAME \
        --custom-cpu=NUMBER_OF_VCPUS \
        --custom-memory=NUMBER_OF_MB \
        --custom-vm-type=MACHINE_TYPE \
        --custom-extension

다음을 바꿉니다.

  • INSTANCE_NAME: 인스턴스 이름
  • NUMBER_OF_VCPUS: vCPU 수
  • NUMBER_OF_MB: 메모리 양(MB 또는 GB)
  • MACHINE_TYPE: 머신 유형(예: N2)

다음 예시는 Google Cloud CLI 옵션을 사용하는 vCPU 48개와 메모리 310GB가 있는 N2 커스텀 머신 유형입니다.

  gcloud compute instances create example-instance \
    --custom-cpu=48 --custom-memory=317440 --custom-extension --custom-vm-type=n2

--custom-memory 옵션을 사용하는 경우에는 총 메모리 양을 GB 또는 MB 단위로 지정합니다. 속성은 정수여야 하며, 메모리 증분 값을 0.25GB로 지정하려면 MB로 변환합니다.

E2 공유 코어 커스텀 머신 유형의 경우 동일한 gcloud compute instances create 명령어를 사용하고 공유 코어 머신 크기(micro, small, medium)를 포함합니다. vCPU 및 메모리는 제한적입니다.

  gcloud compute instances create INSTANCE_NAME\
    --machine-type=MACHINE_TYPE-AMOUNT_OF_MEMORY_MB

다음을 바꿉니다.

  • INSTANCE_NAME: 인스턴스 이름
  • MACHINE_TYPE: E2 small
  • AMOUNT_OF_MEMORY_MB: 메모리 양(MB 또는 GB)

다음 예시는 vCPU 0.5개와 메모리 2.25GB가 있는 E2 공유 코어 small 커스텀 머신 유형입니다.

  gcloud compute instances create example-instance \
    --machine-type=e2-custom-small-2304

Terraform

Terraform 코드를 생성하려면 Google Cloud 콘솔에서 상응하는 코드 구성요소를 사용하면 됩니다.
  1. Google Cloud 콘솔에서 VM 인스턴스 페이지로 이동합니다.

    VM 인스턴스로 이동

  2. 인스턴스 만들기를 클릭합니다.
  3. 원하는 매개변수를 지정합니다.
  4. 페이지 상단 또는 하단에서 상응하는 코드를 클릭한 후 Terraform 탭을 클릭하여 Terraform 코드를 확인합니다.

Go

이 샘플을 사용해 보기 전에 Compute Engine 빠른 시작: 클라이언트 라이브러리 사용Go 설정 안내를 따르세요. 자세한 내용은 Compute Engine Go API 참고 문서를 확인하세요.

Compute Engine에 인증하려면 애플리케이션 기본 사용자 인증 정보를 설정합니다. 자세한 내용은 로컬 개발 환경의 인증 설정을 참조하세요.

import (
	"context"
	"fmt"
	"io"

	compute "cloud.google.com/go/compute/apiv1"
	computepb "cloud.google.com/go/compute/apiv1/computepb"
	"google.golang.org/protobuf/proto"
)

func customMachineTypeURI(zone, cpuSeries string, coreCount, memory int) (string, error) {
	const (
		n1       = "custom"
		n2       = "n2-custom"
		n2d      = "n2d-custom"
		e2       = "e2-custom"
		e2Micro  = "e2-custom-micro"
		e2Small  = "e2-custom-small"
		e2Medium = "e2-custom-medium"
	)

	type typeLimit struct {
		allowedCores     []int
		minMemPerCore    int
		maxMemPerCore    int
		allowExtraMemory bool
		extraMemoryLimit int
	}

	makeRange := func(start, end, step int) []int {
		if step <= 0 || end < start {
			return []int{}
		}
		s := make([]int, 0, 1+(end-start)/step)
		for start <= end {
			s = append(s, start)
			start += step
		}
		return s
	}

	containsString := func(s []string, str string) bool {
		for _, v := range s {
			if v == str {
				return true
			}
		}

		return false
	}

	containsInt := func(nums []int, n int) bool {
		for _, v := range nums {
			if v == n {
				return true
			}
		}

		return false
	}

	var (
		cpuSeriesE2Limit = typeLimit{
			allowedCores:  makeRange(2, 33, 2),
			minMemPerCore: 512,
			maxMemPerCore: 8192,
		}
		cpuSeriesE2MicroLimit  = typeLimit{minMemPerCore: 1024, maxMemPerCore: 2048}
		cpuSeriesE2SmallLimit  = typeLimit{minMemPerCore: 2048, maxMemPerCore: 4096}
		cpuSeriesE2MeidumLimit = typeLimit{minMemPerCore: 4096, maxMemPerCore: 8192}
		cpuSeriesN2Limit       = typeLimit{
			allowedCores:  append(makeRange(2, 33, 2), makeRange(36, 129, 4)...),
			minMemPerCore: 512, maxMemPerCore: 8192,
			allowExtraMemory: true,
			extraMemoryLimit: 624 << 10,
		}
		cpuSeriesN2DLimit = typeLimit{
			allowedCores:  []int{2, 4, 8, 16, 32, 48, 64, 80, 96},
			minMemPerCore: 512, maxMemPerCore: 8192,
			allowExtraMemory: true,
			extraMemoryLimit: 768 << 10,
		}
		cpuSeriesN1Limit = typeLimit{
			allowedCores:     append([]int{1}, makeRange(2, 97, 2)...),
			minMemPerCore:    922,
			maxMemPerCore:    6656,
			allowExtraMemory: true,
			extraMemoryLimit: 624 << 10,
		}
	)

	typeLimitsMap := map[string]typeLimit{
		n1:       cpuSeriesN1Limit,
		n2:       cpuSeriesN2Limit,
		n2d:      cpuSeriesN2DLimit,
		e2:       cpuSeriesE2Limit,
		e2Micro:  cpuSeriesE2MicroLimit,
		e2Small:  cpuSeriesE2SmallLimit,
		e2Medium: cpuSeriesE2MeidumLimit,
	}

	if !containsString([]string{e2, n1, n2, n2d}, cpuSeries) {
		return "", fmt.Errorf("incorrect cpu type: %v", cpuSeries)
	}

	tl := typeLimitsMap[cpuSeries]

	// Check whether the requested parameters are allowed.
	// Find more information about limitations of custom machine types at:
	// https://cloud.google.com/compute/docs/general-purpose-machines#custom_machine_types

	// Check the number of cores
	if len(tl.allowedCores) > 0 && !containsInt(tl.allowedCores, coreCount) {
		return "", fmt.Errorf(
			"invalid number of cores requested. Allowed number of cores for %v is: %v",
			cpuSeries,
			tl.allowedCores,
		)
	}

	// Memory must be a multiple of 256 MB
	if memory%256 != 0 {
		return "", fmt.Errorf("requested memory must be a multiple of 256 MB")
	}

	// Check if the requested memory isn't too little
	if memory < coreCount*tl.minMemPerCore {
		return "", fmt.Errorf(
			"requested memory is too low. Minimal memory for %v is %v MB per core",
			cpuSeries,
			tl.minMemPerCore,
		)
	}

	// Check if the requested memory isn't too much
	if memory > coreCount*tl.maxMemPerCore && !tl.allowExtraMemory {
		return "", fmt.Errorf(
			"requested memory is too large.. Maximum memory allowed for %v is %v MB per core",
			cpuSeries,
			tl.maxMemPerCore,
		)
	}
	if memory > tl.extraMemoryLimit && tl.allowExtraMemory {
		return "", fmt.Errorf(
			"requested memory is too large.. Maximum memory allowed for %v is %v MB",
			cpuSeries,
			tl.extraMemoryLimit,
		)
	}

	// Return the custom machine type in form of a string acceptable by Compute Engine API.
	if containsString([]string{e2Small, e2Micro, e2Medium}, cpuSeries) {
		return fmt.Sprintf("zones/%v/machineTypes/%v-%v", zone, cpuSeries, memory), nil
	}

	if memory > coreCount*tl.maxMemPerCore {
		return fmt.Sprintf(
			"zones/%v/machineTypes/%v-%v-%v-ext",
			zone,
			cpuSeries,
			coreCount,
			memory,
		), nil
	}

	return fmt.Sprintf("zones/%v/machineTypes/%v-%v-%v", zone, cpuSeries, coreCount, memory), nil
}

// createInstanceWithCustomMachineTypeWithHelper creates a new VM instance with a custom machine type.
func createInstanceWithCustomMachineTypeWithHelper(
	w io.Writer,
	projectID, zone, instanceName, cpuSeries string,
	coreCount, memory int,
) error {
	// projectID := "your_project_id"
	// zone := "europe-central2-b"
	// instanceName := "your_instance_name"
	// cpuSeries := "e2-custom-micro" // the type of CPU you want to use"
	// coreCount := 2 // number of CPU cores you want to use.
	// memory := 256 // the amount of memory for the VM instance, in megabytes.

	machineType, err := customMachineTypeURI(zone, cpuSeries, coreCount, memory)
	if err != nil {
		return fmt.Errorf("unable to create custom machine type string: %w", err)
	}

	ctx := context.Background()
	instancesClient, err := compute.NewInstancesRESTClient(ctx)
	if err != nil {
		return fmt.Errorf("NewInstancesRESTClient: %w", err)
	}
	defer instancesClient.Close()

	req := &computepb.InsertInstanceRequest{
		Project: projectID,
		Zone:    zone,
		InstanceResource: &computepb.Instance{
			Name: proto.String(instanceName),
			Disks: []*computepb.AttachedDisk{
				{
					InitializeParams: &computepb.AttachedDiskInitializeParams{
						DiskSizeGb: proto.Int64(10),
						SourceImage: proto.String(
							"projects/debian-cloud/global/images/family/debian-12",
						),
					},
					AutoDelete: proto.Bool(true),
					Boot:       proto.Bool(true),
				},
			},
			MachineType: proto.String(machineType),
			NetworkInterfaces: []*computepb.NetworkInterface{
				{
					Name: proto.String("global/networks/default"),
				},
			},
		},
	}

	op, err := instancesClient.Insert(ctx, req)
	if err != nil {
		return fmt.Errorf("unable to create instance: %w", err)
	}

	if err = op.Wait(ctx); err != nil {
		return fmt.Errorf("unable to wait for the operation: %w", err)
	}

	fmt.Fprintf(w, "Instance created\n")

	return nil
}

자바

이 샘플을 사용해 보기 전에 Compute Engine 빠른 시작: 클라이언트 라이브러리 사용Java 설정 안내를 따르세요. 자세한 내용은 Compute Engine Java API 참고 문서를 확인하세요.

Compute Engine에 인증하려면 애플리케이션 기본 사용자 인증 정보를 설정합니다. 자세한 내용은 로컬 개발 환경의 인증 설정을 참조하세요.


import com.google.cloud.compute.v1.AttachedDisk;
import com.google.cloud.compute.v1.AttachedDiskInitializeParams;
import com.google.cloud.compute.v1.InsertInstanceRequest;
import com.google.cloud.compute.v1.Instance;
import com.google.cloud.compute.v1.InstancesClient;
import com.google.cloud.compute.v1.NetworkInterface;
import com.google.cloud.compute.v1.Operation;
import com.google.common.collect.ImmutableMap;
import java.io.IOException;
import java.util.Arrays;
import java.util.Collections;
import java.util.Map;
import java.util.Objects;
import java.util.concurrent.ConcurrentHashMap;
import java.util.concurrent.ExecutionException;
import java.util.concurrent.TimeUnit;
import java.util.concurrent.TimeoutException;
import java.util.stream.IntStream;

public class CreateWithHelper {

  // This class defines the configurable parameters for a custom VM.
  static final class TypeLimits {

    int[] allowedCores;
    int minMemPerCore;
    int maxMemPerCore;
    int extraMemoryLimit;
    boolean allowExtraMemory;

    TypeLimits(int[] allowedCores, int minMemPerCore, int maxMemPerCore, boolean allowExtraMemory,
        int extraMemoryLimit) {
      this.allowedCores = allowedCores;
      this.minMemPerCore = minMemPerCore;
      this.maxMemPerCore = maxMemPerCore;
      this.allowExtraMemory = allowExtraMemory;
      this.extraMemoryLimit = extraMemoryLimit;
    }
  }

  public enum CpuSeries {
    N1("custom"),
    N2("n2-custom"),
    N2D("n2d-custom"),
    E2("e2-custom"),
    E2_MICRO("e2-custom-micro"),
    E2_SMALL("e2-custom-small"),
    E2_MEDIUM("e2-custom-medium");

    private static final Map<String, CpuSeries> ENUM_MAP;

    static {
      ENUM_MAP = init();
    }

    // Build an immutable map of String name to enum pairs.
    public static Map<String, CpuSeries> init() {
      Map<String, CpuSeries> map = new ConcurrentHashMap<>();
      for (CpuSeries instance : CpuSeries.values()) {
        map.put(instance.getCpuSeries(), instance);
      }
      return Collections.unmodifiableMap(map);
    }

    private final String cpuSeries;

    CpuSeries(String cpuSeries) {
      this.cpuSeries = cpuSeries;
    }

    public static CpuSeries get(String name) {
      return ENUM_MAP.get(name);
    }

    public String getCpuSeries() {
      return this.cpuSeries;
    }
  }

  // This enum correlates a machine type with its limits.
  // The limits for various CPU types are described in:
  // https://cloud.google.com/compute/docs/general-purpose-machines
  enum Limits {
    CPUSeries_E2(new TypeLimits(getNumsInRangeWithStep(2, 33, 2), 512, 8192, false, 0)),
    CPUSeries_E2MICRO(new TypeLimits(new int[]{}, 1024, 2048, false, 0)),
    CPUSeries_E2SMALL(new TypeLimits(new int[]{}, 2048, 4096, false, 0)),
    CPUSeries_E2MEDIUM(new TypeLimits(new int[]{}, 4096, 8192, false, 0)),
    CPUSeries_N2(
        new TypeLimits(concat(getNumsInRangeWithStep(2, 33, 2), getNumsInRangeWithStep(36, 129, 4)),
            512, 8192, true, gbToMb(624))),
    CPUSeries_N2D(
        new TypeLimits(new int[]{2, 4, 8, 16, 32, 48, 64, 80, 96}, 512, 8192, true, gbToMb(768))),
    CPUSeries_N1(
        new TypeLimits(concat(new int[]{1}, getNumsInRangeWithStep(2, 97, 2)), 922, 6656, true,
            gbToMb(624)));

    private final TypeLimits typeLimits;

    Limits(TypeLimits typeLimits) {
      this.typeLimits = typeLimits;
    }

    public TypeLimits getTypeLimits() {
      return typeLimits;
    }
  }

  static ImmutableMap<String, Limits> typeLimitsMap = ImmutableMap.<String, Limits>builder()
      .put("N1", Limits.CPUSeries_N1)
      .put("N2", Limits.CPUSeries_N2)
      .put("N2D", Limits.CPUSeries_N2D)
      .put("E2", Limits.CPUSeries_E2)
      .put("E2_MICRO", Limits.CPUSeries_E2MICRO)
      .put("E2_SMALL", Limits.CPUSeries_E2SMALL)
      .put("E2_MEDIUM", Limits.CPUSeries_E2SMALL)
      .build();

  // Returns the array of integers within the given range, incremented by the specified step.
  // start (inclusive): starting number of the range
  // stop (inclusive): ending number of the range
  // step : increment value
  static int[] getNumsInRangeWithStep(int start, int stop, int step) {
    return IntStream.range(start, stop).filter(x -> (x - start) % step == 0).toArray();
  }

  static int gbToMb(int value) {
    return value << 10;
  }

  static int[] concat(int[] a, int[] b) {
    int[] result = new int[a.length + b.length];
    System.arraycopy(a, 0, result, 0, a.length);
    System.arraycopy(b, 0, result, a.length, b.length);
    return result;
  }

  public static void main(String[] args)
      throws IOException, ExecutionException, InterruptedException, TimeoutException {
    // TODO(developer): Replace these variables before running the sample.
    // Project ID or project number of the Cloud project you want to use.
    String projectId = "your-google-cloud-project-id";
    // Name of the zone to create the instance in. For example: "us-west3-b".
    String zone = "google-cloud-zone";
    // Name of the new virtual machine (VM) instance.
    String instanceName = "instance-name";
    String cpuSeries = "N1";
    // Number of CPU cores you want to use.
    int coreCount = 2;
    // The amount of memory for the VM instance, in megabytes.
    int memory = 256;

    createInstanceWithCustomMachineTypeWithHelper(
        projectId, zone, instanceName, cpuSeries, coreCount, memory);
  }

  // Create a VM instance with a custom machine type.
  public static void createInstanceWithCustomMachineTypeWithHelper(
      String project, String zone, String instanceName, String cpuSeries, int coreCount, int memory)
      throws IOException, ExecutionException, InterruptedException, TimeoutException {
    // Construct the URI string identifying the machine type.
    String machineTypeUri = customMachineTypeUri(zone, cpuSeries, coreCount, memory);

    // Initialize client that will be used to send requests. This client only needs to be created
    // once, and can be reused for multiple requests. After completing all of your requests, call
    // the `instancesClient.close()` method on the client to safely
    // clean up any remaining background resources.
    try (InstancesClient instancesClient = InstancesClient.create()) {

      AttachedDisk attachedDisk = AttachedDisk.newBuilder()
          .setInitializeParams(
              // Describe the size and source image of the boot disk to attach to the instance.
              // The list of public images available in Compute Engine can be found here:
              // https://cloud.google.com/compute/docs/images#list_of_public_images_available_on
              AttachedDiskInitializeParams.newBuilder()
                  .setSourceImage(
                      String.format("projects/%s/global/images/family/%s", "debian-cloud",
                          "debian-11"))
                  .setDiskSizeGb(10)
                  .build()
          )
          // Remember to set auto_delete to True if you want the disk to be deleted when you delete
          // your VM instance.
          .setAutoDelete(true)
          .setBoot(true)
          .build();

      // Create the Instance object with the relevant information.
      Instance instance = Instance.newBuilder()
          .setName(instanceName)
          .addDisks(attachedDisk)
          .setMachineType(machineTypeUri)
          .addNetworkInterfaces(
              NetworkInterface.newBuilder().setName("global/networks/default").build())
          .build();

      // Create the insert instance request object.
      InsertInstanceRequest insertInstanceRequest = InsertInstanceRequest.newBuilder()
          .setProject(project)
          .setZone(zone)
          .setInstanceResource(instance)
          .build();

      // Invoke the API with the request object and wait for the operation to complete.
      Operation response = instancesClient.insertAsync(insertInstanceRequest)
          .get(3, TimeUnit.MINUTES);

      // Check for errors.
      if (response.hasError()) {
        throw new Error("Instance creation failed!!" + response);
      }
      System.out.printf("Instance created : %s", instanceName);
      System.out.println("Operation Status: " + response.getStatus());
    }
  }

  public static String customMachineTypeUri(String zone, String cpuSeries, int coreCount,
      int memory) {

    if (!Arrays.asList(CpuSeries.E2.cpuSeries, CpuSeries.N1.cpuSeries, CpuSeries.N2.cpuSeries,
        CpuSeries.N2D.cpuSeries).contains(cpuSeries)) {
      throw new Error(String.format("Incorrect cpu type: %s", cpuSeries));
    }

    TypeLimits typeLimit = Objects.requireNonNull(
        typeLimitsMap.get(CpuSeries.get(cpuSeries).name())).typeLimits;

    // Perform the following checks to verify if the requested parameters are allowed.
    // Find more information about limitations of custom machine types at:
    // https://cloud.google.com/compute/docs/general-purpose-machines#custom_machine_types

    // 1. Check the number of cores and if the coreCount is present in allowedCores.
    if (typeLimit.allowedCores.length > 0 && Arrays.stream(typeLimit.allowedCores)
        .noneMatch(x -> x == coreCount)) {
      throw new Error(String.format(
          "Invalid number of cores requested. "
              + "Number of cores requested for CPU %s should be one of: %s",
          cpuSeries,
          Arrays.toString(typeLimit.allowedCores)));
    }

    // 2. Memory must be a multiple of 256 MB
    if (memory % 256 != 0) {
      throw new Error("Requested memory must be a multiple of 256 MB");
    }

    // 3. Check if the requested memory isn't too little
    if (memory < coreCount * typeLimit.minMemPerCore) {
      throw new Error(
          String.format("Requested memory is too low. Minimum memory for %s is %s MB per core",
              cpuSeries, typeLimit.minMemPerCore));
    }

    // 4. Check if the requested memory isn't too much
    if (memory > coreCount * typeLimit.maxMemPerCore && !typeLimit.allowExtraMemory) {
      throw new Error(String.format(
          "Requested memory is too large.. Maximum memory allowed for %s is %s MB per core",
          cpuSeries, typeLimit.extraMemoryLimit));
    }

    // 5. Check if the requested memory isn't too large
    if (memory > typeLimit.extraMemoryLimit && typeLimit.allowExtraMemory) {
      throw new Error(
          String.format("Requested memory is too large.. Maximum memory allowed for %s is %s MB",
              cpuSeries, typeLimit.extraMemoryLimit));
    }

    // Check if the CPU Series is E2 and return the custom machine type in the form of a string
    // acceptable by Compute Engine API.
    if (Arrays.asList(CpuSeries.E2_SMALL.cpuSeries, CpuSeries.E2_MICRO.cpuSeries,
        CpuSeries.E2_MEDIUM.cpuSeries).contains(cpuSeries)) {
      return String.format("zones/%s/machineTypes/%s-%s", zone, cpuSeries, memory);
    }

    // Check if extended memory was requested and return the extended custom machine type
    // in the form of a string acceptable by Compute Engine API.
    if (memory > coreCount * typeLimit.maxMemPerCore) {
      return String.format("zones/%s/machineTypes/%s-%s-%s-ext", zone, cpuSeries, coreCount,
          memory);
    }

    // Return the custom machine type in the form of a standard string
    // acceptable by Compute Engine API.
    return String.format("zones/%s/machineTypes/%s-%s-%s", zone, cpuSeries, coreCount, memory);
  }
}

Node.js

이 샘플을 사용해 보기 전에 Compute Engine 빠른 시작: 클라이언트 라이브러리 사용Node.js 설정 안내를 따르세요. 자세한 내용은 Compute Engine Node.js API 참고 문서를 확인하세요.

Compute Engine에 인증하려면 애플리케이션 기본 사용자 인증 정보를 설정합니다. 자세한 내용은 로컬 개발 환경의 인증 설정을 참조하세요.

/**
 * TODO(developer): Uncomment and replace these variables before running the sample.
 */
// const projectId = 'YOUR_PROJECT_ID';
// const zone = 'europe-central2-b';
// const instanceName = 'YOUR_INSTANCE_NAME';
// const cpuSeries = 'N1';
// const coreCount = 2
// const memory = 256

const compute = require('@google-cloud/compute');

function range(from, to, step) {
  return [...Array(Math.floor((to - from) / step) + 1)].map(
    (_, i) => from + i * step
  );
}

class CustomMachineType {
  constructor(zone, cpuSeries, coreCount, memory) {
    this.zone = zone;
    this.cpuSeries = cpuSeries;
    this.coreCount = coreCount;
    this.memory = memory;

    this.N1 = 'custom';
    this.N2 = 'n2-custom';
    this.N2D = 'n2d-custom';
    this.E2 = 'e2-custom';
    this.E2Micro = 'e2-custom-micro';
    this.E2Small = 'e2-custom-small';
    this.E2Medium = 'e2-custom-medium';

    this.CpuSeriesE2Limit = {
      allowedCores: range(2, 33, 2),
      minMemPerCore: 512,
      maxMemPerCore: 8192,
      allowExtraMemory: false,
      extraMemoryLimit: 0,
    };

    this.CpuSeriesE2MicroLimit = {
      allowedCores: [],
      minMemPerCore: 1024,
      maxMemPerCore: 2048,
      allowExtraMemory: false,
      extraMemoryLimit: 0,
    };

    this.CpuSeriesE2SmallLimit = {
      allowedCores: [],
      minMemPerCore: 2048,
      maxMemPerCore: 4096,
      allowExtraMemory: false,
      extraMemoryLimit: 0,
    };

    this.CpuSeriesE2MediumLimit = {
      allowedCores: [],
      minMemPerCore: 4096,
      maxMemPerCore: 8192,
      allowExtraMemory: false,
      extraMemoryLimit: 0,
    };

    this.CpuSeriesN2Limit = {
      allowedCores: [...range(2, 33, 2), ...range(36, 129, 4)],
      minMemPerCore: 512,
      maxMemPerCore: 8192,
      allowExtraMemory: true,
      extraMemoryLimit: 624 << 10,
    };

    this.CpuSeriesN2DLimit = {
      allowedCores: [2, 4, 8, 16, 32, 48, 64, 80, 96],
      minMemPerCore: 512,
      maxMemPerCore: 8192,
      allowExtraMemory: true,
      extraMemoryLimit: 768 << 10,
    };

    this.CpuSeriesN1Limit = {
      allowedCores: [1, range(2, 97, 2)],
      minMemPerCore: 922,
      maxMemPerCore: 6656,
      allowExtraMemory: true,
      extraMemoryLimit: 624 << 10,
    };

    this.TYPE_LIMITS = {
      [this.N1]: this.CpuSeriesN1Limit,
      [this.N2]: this.CpuSeriesN2Limit,
      [this.N2D]: this.CpuSeriesN2DLimit,
      [this.E2]: this.CpuSeriesE2Limit,
      [this.E2Micro]: this.CpuSeriesE2MicroLimit,
      [this.E2Small]: this.CpuSeriesE2SmallLimit,
      [this.E2Medium]: this.CpuSeriesE2MediumLimit,
    };

    if (![this.E2, this.N1, this.N2, this.N2D].includes(cpuSeries)) {
      throw new Error(`Incorrect CPU type: ${this.cpuSeries}`);
    }

    this.typeLimit = this.TYPE_LIMITS[this.cpuSeries];

    // Check whether the requested parameters are allowed.
    // Find more information about limitations of custom machine types at:
    // https://cloud.google.com/compute/docs/general-purpose-machines#custom_machine_types

    // Check the number of cores
    if (
      this.typeLimit.allowedCores.length > 0 &&
      !this.typeLimit.allowedCores.includes(coreCount)
    ) {
      throw new Error(
        `Invalid number of cores requested. Allowed number of cores for ${this.cpuSeries} is: ${this.typeLimit.allowedCores}`
      );
    }

    // Memory must be a multiple of 256 MB
    if (this.memory % 256 !== 0) {
      throw new Error('Requested memory must be a multiple of 256 MB');
    }

    // Check if the requested memory isn't too little
    if (this.memory < this.coreCount * this.typeLimit.minMemPerCore) {
      throw new Error(
        `Requested memory is too low. Minimal memory for ${this.cpuSeries} is ${this.typeLimit.minMemPerCore} MB per core`
      );
    }

    // Check if the requested memory isn't too much
    if (
      this.memory > this.coreCount * this.typeLimit.maxMemPerCore &&
      !this.typeLimit.allowExtraMemory
    ) {
      throw new Error(
        `Requested memory is too large.. Maximum memory allowed for ${this.cpuSeries} is ${this.typeLimit.maxMemPerCore} MB per core`
      );
    }

    if (
      this.memory > this.typeLimit.extraMemoryLimit &&
      this.typeLimit.allowExtraMemory
    ) {
      throw new Error(
        `Requested memory is too large.. Maximum memory allowed for ${this.cpuSeries} is ${this.typeLimit.extraMemoryLimit} MB`
      );
    }
  }

  // Returns the custom machine type in form of a string acceptable by Compute Engine API.
  getMachineTypeURI() {
    if (
      [this.E2Small, this.E2Micro, this.E2Medium].includes(this.cpuSeries)
    ) {
      return `zones/${this.zone}/machineTypes/${this.cpuSeries}-${this.memory}`;
    }

    if (this.memory > this.coreCount * this.typeLimit.maxMemPerCore) {
      return `zones/${this.zone}/machineTypes/${this.cpuSeries}-${this.coreCount}-${this.memory}-ext`;
    }

    return `zones/${zone}/machineTypes/${this.cpuSeries}-${this.coreCount}-${this.memory}`;
  }
}

async function createInstanceWithCustomMachineTypeWithHelper() {
  const instancesClient = new compute.InstancesClient();

  const machineType = new CustomMachineType(
    zone,
    cpuSeries,
    coreCount,
    memory
  ).getMachineTypeURI();

  const [response] = await instancesClient.insert({
    instanceResource: {
      name: instanceName,
      disks: [
        {
          initializeParams: {
            diskSizeGb: '64',
            sourceImage:
              'projects/debian-cloud/global/images/family/debian-11/',
          },
          autoDelete: true,
          boot: true,
        },
      ],
      machineType,
      networkInterfaces: [
        {
          name: 'global/networks/default',
        },
      ],
    },
    project: projectId,
    zone,
  });
  let operation = response.latestResponse;
  const operationsClient = new compute.ZoneOperationsClient();

  // Wait for the create operation to complete.
  while (operation.status !== 'DONE') {
    [operation] = await operationsClient.wait({
      operation: operation.name,
      project: projectId,
      zone: operation.zone.split('/').pop(),
    });
  }

  console.log('Instance created.');
}

createInstanceWithCustomMachineTypeWithHelper();

Python

이 샘플을 사용해 보기 전에 Compute Engine 빠른 시작: 클라이언트 라이브러리 사용Python 설정 안내를 따르세요. 자세한 내용은 Compute Engine Python API 참고 문서를 확인하세요.

Compute Engine에 인증하려면 애플리케이션 기본 사용자 인증 정보를 설정합니다. 자세한 내용은 로컬 개발 환경의 인증 설정을 참조하세요.

from __future__ import annotations

from collections import namedtuple
from enum import Enum
from enum import unique
import re
import sys
from typing import Any
import warnings

from google.api_core.extended_operation import ExtendedOperation
from google.cloud import compute_v1


def gb_to_mb(value: int) -> int:
    return value << 10


class CustomMachineType:
    """
    Allows to create custom machine types to be used with the VM instances.
    """

    @unique
    class CPUSeries(Enum):
        N1 = "custom"
        N2 = "n2-custom"
        N2D = "n2d-custom"
        E2 = "e2-custom"
        E2_MICRO = "e2-custom-micro"
        E2_SMALL = "e2-custom-small"
        E2_MEDIUM = "e2-custom-medium"

    TypeLimits = namedtuple(
        "TypeLimits",
        [
            "allowed_cores",
            "min_mem_per_core",
            "max_mem_per_core",
            "allow_extra_memory",
            "extra_memory_limit",
        ],
    )

    # The limits for various CPU types are described on:
    # https://cloud.google.com/compute/docs/general-purpose-machines
    LIMITS = {
        CPUSeries.E2: TypeLimits(frozenset(range(2, 33, 2)), 512, 8192, False, 0),
        CPUSeries.E2_MICRO: TypeLimits(frozenset(), 1024, 2048, False, 0),
        CPUSeries.E2_SMALL: TypeLimits(frozenset(), 2048, 4096, False, 0),
        CPUSeries.E2_MEDIUM: TypeLimits(frozenset(), 4096, 8192, False, 0),
        CPUSeries.N2: TypeLimits(
            frozenset(range(2, 33, 2)).union(set(range(36, 129, 4))),
            512,
            8192,
            True,
            gb_to_mb(624),
        ),
        CPUSeries.N2D: TypeLimits(
            frozenset({2, 4, 8, 16, 32, 48, 64, 80, 96}), 512, 8192, True, gb_to_mb(768)
        ),
        CPUSeries.N1: TypeLimits(
            frozenset({1}.union(range(2, 97, 2))), 922, 6656, True, gb_to_mb(624)
        ),
    }

    def __init__(
        self, zone: str, cpu_series: CPUSeries, memory_mb: int, core_count: int = 0
    ):
        self.zone = zone
        self.cpu_series = cpu_series
        self.limits = self.LIMITS[self.cpu_series]
        # Shared machine types (e2-small, e2-medium and e2-micro) always have
        # 2 vCPUs: https://cloud.google.com/compute/docs/general-purpose-machines#e2_limitations
        self.core_count = 2 if self.is_shared() else core_count
        self.memory_mb = memory_mb
        self._checked = False
        self._check_parameters()
        self.extra_memory_used = self._check_extra_memory()

    def is_shared(self):
        return self.cpu_series in (
            CustomMachineType.CPUSeries.E2_SMALL,
            CustomMachineType.CPUSeries.E2_MICRO,
            CustomMachineType.CPUSeries.E2_MEDIUM,
        )

    def _check_extra_memory(self) -> bool:
        if self._checked:
            return self.memory_mb > self.core_count * self.limits.max_mem_per_core
        else:
            raise RuntimeError(
                "You need to call _check_parameters() before calling _check_extra_memory()"
            )

    def _check_parameters(self):
        """
        Check whether the requested parameters are allowed. Find more information about limitations of custom machine
        types at: https://cloud.google.com/compute/docs/general-purpose-machines#custom_machine_types
        """
        # Check the number of cores
        if (
            self.limits.allowed_cores
            and self.core_count not in self.limits.allowed_cores
        ):
            raise RuntimeError(
                f"Invalid number of cores requested. Allowed number of cores for {self.cpu_series.name} is: {sorted(self.limits.allowed_cores)}"
            )

        # Memory must be a multiple of 256 MB
        if self.memory_mb % 256 != 0:
            raise RuntimeError("Requested memory must be a multiple of 256 MB.")

        # Check if the requested memory isn't too little
        if self.memory_mb < self.core_count * self.limits.min_mem_per_core:
            raise RuntimeError(
                f"Requested memory is too low. Minimal memory for {self.cpu_series.name} is {self.limits.min_mem_per_core} MB per core."
            )

        # Check if the requested memory isn't too much
        if self.memory_mb > self.core_count * self.limits.max_mem_per_core:
            if self.limits.allow_extra_memory:
                if self.memory_mb > self.limits.extra_memory_limit:
                    raise RuntimeError(
                        f"Requested memory is too large.. Maximum memory allowed for {self.cpu_series.name} is {self.limits.extra_memory_limit} MB."
                    )
            else:
                raise RuntimeError(
                    f"Requested memory is too large.. Maximum memory allowed for {self.cpu_series.name} is {self.limits.max_mem_per_core} MB per core."
                )

        self._checked = True

    def __str__(self) -> str:
        """
        Return the custom machine type in form of a string acceptable by Compute Engine API.
        """
        if self.cpu_series in {
            self.CPUSeries.E2_SMALL,
            self.CPUSeries.E2_MICRO,
            self.CPUSeries.E2_MEDIUM,
        }:
            return f"zones/{self.zone}/machineTypes/{self.cpu_series.value}-{self.memory_mb}"

        if self.extra_memory_used:
            return f"zones/{self.zone}/machineTypes/{self.cpu_series.value}-{self.core_count}-{self.memory_mb}-ext"

        return f"zones/{self.zone}/machineTypes/{self.cpu_series.value}-{self.core_count}-{self.memory_mb}"

    def short_type_str(self) -> str:
        """
        Return machine type in a format without the zone. For example, n2-custom-0-10240.
        This format is used to create instance templates.
        """
        return str(self).rsplit("/", maxsplit=1)[1]

    @classmethod
    def from_str(cls, machine_type: str):
        """
        Construct a new object from a string. The string needs to be a valid custom machine type like:
         - https://www.googleapis.com/compute/v1/projects/diregapic-mestiv/zones/us-central1-b/machineTypes/e2-custom-4-8192
         - zones/us-central1-b/machineTypes/e2-custom-4-8192
         - e2-custom-4-8192 (in this case, the zone parameter will not be set)
        """
        zone = None
        if machine_type.startswith("http"):
            machine_type = machine_type[machine_type.find("zones/") :]

        if machine_type.startswith("zones/"):
            _, zone, _, machine_type = machine_type.split("/")

        extra_mem = machine_type.endswith("-ext")

        if machine_type.startswith("custom"):
            cpu = cls.CPUSeries.N1
            _, cores, memory = machine_type.rsplit("-", maxsplit=2)
        else:
            if extra_mem:
                cpu_series, _, cores, memory, _ = machine_type.split("-")
            else:
                cpu_series, _, cores, memory = machine_type.split("-")
            if cpu_series == "n2":
                cpu = cls.CPUSeries.N2
            elif cpu_series == "n2d":
                cpu = cls.CPUSeries.N2D
            elif cpu_series == "e2":
                cpu = cls.CPUSeries.E2
                if cores == "micro":
                    cpu = cls.CPUSeries.E2_MICRO
                    cores = 2
                elif cores == "small":
                    cpu = cls.CPUSeries.E2_SMALL
                    cores = 2
                elif cores == "medium":
                    cpu = cls.CPUSeries.E2_MEDIUM
                    cores = 2
            else:
                raise RuntimeError("Unknown CPU series.")

        cores = int(cores)
        memory = int(memory)

        return cls(zone, cpu, memory, cores)


def get_image_from_family(project: str, family: str) -> compute_v1.Image:
    """
    Retrieve the newest image that is part of a given family in a project.

    Args:
        project: project ID or project number of the Cloud project you want to get image from.
        family: name of the image family you want to get image from.

    Returns:
        An Image object.
    """
    image_client = compute_v1.ImagesClient()
    # List of public operating system (OS) images: https://cloud.google.com/compute/docs/images/os-details
    newest_image = image_client.get_from_family(project=project, family=family)
    return newest_image


def disk_from_image(
    disk_type: str,
    disk_size_gb: int,
    boot: bool,
    source_image: str,
    auto_delete: bool = True,
) -> compute_v1.AttachedDisk:
    """
    Create an AttachedDisk object to be used in VM instance creation. Uses an image as the
    source for the new disk.

    Args:
         disk_type: the type of disk you want to create. This value uses the following format:
            "zones/{zone}/diskTypes/(pd-standard|pd-ssd|pd-balanced|pd-extreme)".
            For example: "zones/us-west3-b/diskTypes/pd-ssd"
        disk_size_gb: size of the new disk in gigabytes
        boot: boolean flag indicating whether this disk should be used as a boot disk of an instance
        source_image: source image to use when creating this disk. You must have read access to this disk. This can be one
            of the publicly available images or an image from one of your projects.
            This value uses the following format: "projects/{project_name}/global/images/{image_name}"
        auto_delete: boolean flag indicating whether this disk should be deleted with the VM that uses it

    Returns:
        AttachedDisk object configured to be created using the specified image.
    """
    boot_disk = compute_v1.AttachedDisk()
    initialize_params = compute_v1.AttachedDiskInitializeParams()
    initialize_params.source_image = source_image
    initialize_params.disk_size_gb = disk_size_gb
    initialize_params.disk_type = disk_type
    boot_disk.initialize_params = initialize_params
    # Remember to set auto_delete to True if you want the disk to be deleted when you delete
    # your VM instance.
    boot_disk.auto_delete = auto_delete
    boot_disk.boot = boot
    return boot_disk


def wait_for_extended_operation(
    operation: ExtendedOperation, verbose_name: str = "operation", timeout: int = 300
) -> Any:
    """
    Waits for the extended (long-running) operation to complete.

    If the operation is successful, it will return its result.
    If the operation ends with an error, an exception will be raised.
    If there were any warnings during the execution of the operation
    they will be printed to sys.stderr.

    Args:
        operation: a long-running operation you want to wait on.
        verbose_name: (optional) a more verbose name of the operation,
            used only during error and warning reporting.
        timeout: how long (in seconds) to wait for operation to finish.
            If None, wait indefinitely.

    Returns:
        Whatever the operation.result() returns.

    Raises:
        This method will raise the exception received from `operation.exception()`
        or RuntimeError if there is no exception set, but there is an `error_code`
        set for the `operation`.

        In case of an operation taking longer than `timeout` seconds to complete,
        a `concurrent.futures.TimeoutError` will be raised.
    """
    result = operation.result(timeout=timeout)

    if operation.error_code:
        print(
            f"Error during {verbose_name}: [Code: {operation.error_code}]: {operation.error_message}",
            file=sys.stderr,
            flush=True,
        )
        print(f"Operation ID: {operation.name}", file=sys.stderr, flush=True)
        raise operation.exception() or RuntimeError(operation.error_message)

    if operation.warnings:
        print(f"Warnings during {verbose_name}:\n", file=sys.stderr, flush=True)
        for warning in operation.warnings:
            print(f" - {warning.code}: {warning.message}", file=sys.stderr, flush=True)

    return result


def create_instance(
    project_id: str,
    zone: str,
    instance_name: str,
    disks: list[compute_v1.AttachedDisk],
    machine_type: str = "n1-standard-1",
    network_link: str = "global/networks/default",
    subnetwork_link: str = None,
    internal_ip: str = None,
    external_access: bool = False,
    external_ipv4: str = None,
    accelerators: list[compute_v1.AcceleratorConfig] = None,
    preemptible: bool = False,
    spot: bool = False,
    instance_termination_action: str = "STOP",
    custom_hostname: str = None,
    delete_protection: bool = False,
) -> compute_v1.Instance:
    """
    Send an instance creation request to the Compute Engine API and wait for it to complete.

    Args:
        project_id: project ID or project number of the Cloud project you want to use.
        zone: name of the zone to create the instance in. For example: "us-west3-b"
        instance_name: name of the new virtual machine (VM) instance.
        disks: a list of compute_v1.AttachedDisk objects describing the disks
            you want to attach to your new instance.
        machine_type: machine type of the VM being created. This value uses the
            following format: "zones/{zone}/machineTypes/{type_name}".
            For example: "zones/europe-west3-c/machineTypes/f1-micro"
        network_link: name of the network you want the new instance to use.
            For example: "global/networks/default" represents the network
            named "default", which is created automatically for each project.
        subnetwork_link: name of the subnetwork you want the new instance to use.
            This value uses the following format:
            "regions/{region}/subnetworks/{subnetwork_name}"
        internal_ip: internal IP address you want to assign to the new instance.
            By default, a free address from the pool of available internal IP addresses of
            used subnet will be used.
        external_access: boolean flag indicating if the instance should have an external IPv4
            address assigned.
        external_ipv4: external IPv4 address to be assigned to this instance. If you specify
            an external IP address, it must live in the same region as the zone of the instance.
            This setting requires `external_access` to be set to True to work.
        accelerators: a list of AcceleratorConfig objects describing the accelerators that will
            be attached to the new instance.
        preemptible: boolean value indicating if the new instance should be preemptible
            or not. Preemptible VMs have been deprecated and you should now use Spot VMs.
        spot: boolean value indicating if the new instance should be a Spot VM or not.
        instance_termination_action: What action should be taken once a Spot VM is terminated.
            Possible values: "STOP", "DELETE"
        custom_hostname: Custom hostname of the new VM instance.
            Custom hostnames must conform to RFC 1035 requirements for valid hostnames.
        delete_protection: boolean value indicating if the new virtual machine should be
            protected against deletion or not.
    Returns:
        Instance object.
    """
    instance_client = compute_v1.InstancesClient()

    # Use the network interface provided in the network_link argument.
    network_interface = compute_v1.NetworkInterface()
    network_interface.network = network_link
    if subnetwork_link:
        network_interface.subnetwork = subnetwork_link

    if internal_ip:
        network_interface.network_i_p = internal_ip

    if external_access:
        access = compute_v1.AccessConfig()
        access.type_ = compute_v1.AccessConfig.Type.ONE_TO_ONE_NAT.name
        access.name = "External NAT"
        access.network_tier = access.NetworkTier.PREMIUM.name
        if external_ipv4:
            access.nat_i_p = external_ipv4
        network_interface.access_configs = [access]

    # Collect information into the Instance object.
    instance = compute_v1.Instance()
    instance.network_interfaces = [network_interface]
    instance.name = instance_name
    instance.disks = disks
    if re.match(r"^zones/[a-z\d\-]+/machineTypes/[a-z\d\-]+$", machine_type):
        instance.machine_type = machine_type
    else:
        instance.machine_type = f"zones/{zone}/machineTypes/{machine_type}"

    instance.scheduling = compute_v1.Scheduling()
    if accelerators:
        instance.guest_accelerators = accelerators
        instance.scheduling.on_host_maintenance = (
            compute_v1.Scheduling.OnHostMaintenance.TERMINATE.name
        )

    if preemptible:
        # Set the preemptible setting
        warnings.warn(
            "Preemptible VMs are being replaced by Spot VMs.", DeprecationWarning
        )
        instance.scheduling = compute_v1.Scheduling()
        instance.scheduling.preemptible = True

    if spot:
        # Set the Spot VM setting
        instance.scheduling.provisioning_model = (
            compute_v1.Scheduling.ProvisioningModel.SPOT.name
        )
        instance.scheduling.instance_termination_action = instance_termination_action

    if custom_hostname is not None:
        # Set the custom hostname for the instance
        instance.hostname = custom_hostname

    if delete_protection:
        # Set the delete protection bit
        instance.deletion_protection = True

    # Prepare the request to insert an instance.
    request = compute_v1.InsertInstanceRequest()
    request.zone = zone
    request.project = project_id
    request.instance_resource = instance

    # Wait for the create operation to complete.
    print(f"Creating the {instance_name} instance in {zone}...")

    operation = instance_client.insert(request=request)

    wait_for_extended_operation(operation, "instance creation")

    print(f"Instance {instance_name} created.")
    return instance_client.get(project=project_id, zone=zone, instance=instance_name)


def create_custom_instance(
    project_id: str,
    zone: str,
    instance_name: str,
    cpu_series: CustomMachineType.CPUSeries,
    core_count: int,
    memory: int,
) -> compute_v1.Instance:
    """
    Create a new VM instance with a custom machine type.

    Args:
        project_id: project ID or project number of the Cloud project you want to use.
        zone: name of the zone to create the instance in. For example: "us-west3-b"
        instance_name: name of the new virtual machine (VM) instance.
        cpu_series: the type of CPU you want to use. Select one value from the CustomMachineType.CPUSeries enum.
            For example: CustomMachineType.CPUSeries.N2
        core_count: number of CPU cores you want to use.
        memory: the amount of memory for the VM instance, in megabytes.

    Return:
        Instance object.
    """
    assert cpu_series in (
        CustomMachineType.CPUSeries.E2,
        CustomMachineType.CPUSeries.N1,
        CustomMachineType.CPUSeries.N2,
        CustomMachineType.CPUSeries.N2D,
    )
    custom_type = CustomMachineType(zone, cpu_series, memory, core_count)

    newest_debian = get_image_from_family(project="debian-cloud", family="debian-12")
    disk_type = f"zones/{zone}/diskTypes/pd-standard"
    disks = [disk_from_image(disk_type, 10, True, newest_debian.self_link)]

    return create_instance(project_id, zone, instance_name, disks, str(custom_type))

REST

instances.insert 메서드를 사용하여 인스턴스 만들기 요청을 생성하고 커스텀 machineType을 지정합니다. 메모리는 MB 단위로 입력합니다.

  • N1 머신 시리즈의 경우 커스텀으로 시작합니다.
  • E2 공유 코어의 경우 NUMBER_OF_CPUs는 micro, small 또는 medium입니다.
  • 확장 메모리를 사용 설정하려면 머신 유형 끝에 -ext를 포함합니다.

POST https://compute.googleapis.com/compute/v1/projects/PROJECT_ID/zones/ZONE/instances

요청 본문 예시:

      {
    "name": "exampleinstance",
    "machineType": "zones/us-central1-a/machineTypes/n2-custom-16-107520",
    "disks": [
      {
        "boot": true,
        "diskSizeGb": 10,
        "initializeParams": {
          "sourceImage": "projects/debian-cloud/global/images/family/debian-11"
        }
      }
    ],
    "networkInterfaces": [
      {
        "network": "global/networks/default"
      }
    ]
  }
```

커스텀 머신 유형으로 선점형 인스턴스인스턴스 그룹을 만들 수도 있습니다.

인스턴스 생성 중에 확장 메모리 추가

확장 메모리를 사용하는 VM 인스턴스를 만들려면 다음 단계를 따르세요.

콘솔

  1. Google Cloud 콘솔에서 인스턴스 만들기 페이지로 이동합니다.

    인스턴스 만들기로 이동

  2. 영역 목록에서 이 VM을 호스팅할 영역을 선택합니다. 선택한 영역의 사용 가능한 머신 유형 계열만 포함하도록 계열 목록이 필터링됩니다.

  3. 머신 구성 섹션에서 범용을 선택합니다.

    1. 시리즈 목록에서 N4, N2, N2D, E2 또는 N1을 선택하여 커스텀 머신 유형을 만듭니다.
    2. vCPU 수를 지정하려면 코어 슬라이더를 드래그하거나 필드에 값을 입력합니다. E2 공유 코어의 경우 체크박스를 선택합니다.
    3. 확장 메모리를 추가하려면 확장 메모리를 선택합니다. 머신 유형의 메모리 양을 지정하려면 메모리 슬라이더를 드래그하거나 필드에 값을 입력합니다. vCPU 및 메모리 양을 수정하면 콘솔에 VM의 예상 비용이 표시됩니다.
  4. 계속해서 VM을 만듭니다.

gcloud

--machine-type 옵션과 함께 gcloud compute instances create 명령어를 사용하여 커스텀 머신을 만듭니다.

  gcloud compute instances create  INSTANCE_NAME\
    --machine-type=MACHINE_TYPE-NUMBER_OF_VCPUS-AMOUNT_OF_MEMORY_MB

다음을 바꿉니다.

  • INSTANCE_NAME: 인스턴스 이름
  • MACHINE_TYPE: 머신 유형(예: N2)
  • NUMBER_OF_VCPUS: vCPU 수
  • AMOUNT_OF_MEMORY_MB: 메모리 양(MB 또는 GB)

다음은 us-central1-a 영역에서 vCPU 48개와 메모리 310GB가 있는 N2 머신 유형을 사용하는 예시입니다.

  gcloud compute instances create example-instance \
    --zone=us-central1-a --machine-type=n2-custom-48-317440

커스텀 E2 공유 코어 머신 유형의 경우 --machine-type 옵션을 사용하고 머신 유형(micro, small, medium)을 표시한 후 메모리 양을 MB 또는 GB로 입력합니다.

Go

이 샘플을 사용해 보기 전에 Compute Engine 빠른 시작: 클라이언트 라이브러리 사용Go 설정 안내를 따르세요. 자세한 내용은 Compute Engine Go API 참고 문서를 확인하세요.

Compute Engine에 인증하려면 애플리케이션 기본 사용자 인증 정보를 설정합니다. 자세한 내용은 로컬 개발 환경의 인증 설정을 참조하세요.

import (
	"context"
	"fmt"
	"io"

	compute "cloud.google.com/go/compute/apiv1"
	computepb "cloud.google.com/go/compute/apiv1/computepb"
	"google.golang.org/protobuf/proto"
)

// createInstanceWithExtraMemWithoutHelper сreates new VM instances with extra memory
// without using a CustomMachineType struct.
func createInstanceWithExtraMemWithoutHelper(
	w io.Writer,
	projectID, zone, instanceName, cpuSeries string,
	coreCount, memory int,
) error {
	// projectID := "your_project_id"
	// zone := "europe-central2-b"
	// instanceName := "your_instance_name"
	// cpuSeries := "N1"
	// coreCount := 2 // number of CPU cores you want to use.
	// memory := 256 // the amount of memory for the VM instance, in megabytes.

	// The coreCount and memory values are not validated anywhere and can be rejected by the API.

	ctx := context.Background()
	instancesClient, err := compute.NewInstancesRESTClient(ctx)
	if err != nil {
		return fmt.Errorf("NewInstancesRESTClient: %w", err)
	}
	defer instancesClient.Close()

	mt := fmt.Sprintf("zones/%s/machineTypes/%v-%v-%v-ext", zone, cpuSeries, coreCount, memory)
	inst := &computepb.Instance{
		Name: proto.String(instanceName),
		Disks: []*computepb.AttachedDisk{
			{
				InitializeParams: &computepb.AttachedDiskInitializeParams{
					DiskSizeGb: proto.Int64(10),
					SourceImage: proto.String(
						"projects/debian-cloud/global/images/family/debian-12",
					),
				},
				AutoDelete: proto.Bool(true),
				Boot:       proto.Bool(true),
			},
		},
		MachineType: proto.String(mt),
		NetworkInterfaces: []*computepb.NetworkInterface{
			{
				Name: proto.String("global/networks/default"),
			},
		},
	}

	req := &computepb.InsertInstanceRequest{
		Project:          projectID,
		Zone:             zone,
		InstanceResource: inst,
	}

	op, err := instancesClient.Insert(ctx, req)
	if err != nil {
		return fmt.Errorf("unable to create instance: %w", err)
	}

	if err = op.Wait(ctx); err != nil {
		return fmt.Errorf("unable to wait for the operation: %w", err)
	}

	fmt.Fprintf(w, "Instance created\n")

	return nil
}

자바

이 샘플을 사용해 보기 전에 Compute Engine 빠른 시작: 클라이언트 라이브러리 사용Java 설정 안내를 따르세요. 자세한 내용은 Compute Engine Java API 참고 문서를 확인하세요.

Compute Engine에 인증하려면 애플리케이션 기본 사용자 인증 정보를 설정합니다. 자세한 내용은 로컬 개발 환경의 인증 설정을 참조하세요.


import com.google.cloud.compute.v1.AttachedDisk;
import com.google.cloud.compute.v1.AttachedDiskInitializeParams;
import com.google.cloud.compute.v1.InsertInstanceRequest;
import com.google.cloud.compute.v1.Instance;
import com.google.cloud.compute.v1.InstancesClient;
import com.google.cloud.compute.v1.NetworkInterface;
import com.google.cloud.compute.v1.Operation;
import java.io.IOException;
import java.util.concurrent.ExecutionException;
import java.util.concurrent.TimeUnit;
import java.util.concurrent.TimeoutException;

public class ExtraMemoryWithoutHelper {

  public static void main(String[] args)
      throws IOException, ExecutionException, InterruptedException, TimeoutException {
    // TODO(developer): Replace these variables before running the sample.
    // Project ID or project number of the Cloud project you want to use.
    String projectId = "your-google-cloud-project-id";
    // Name of the zone to create the instance in. For example: "us-west3-b".
    String zone = "google-cloud-zone";
    // Name of the new virtual machine (VM) instance.
    String instanceName = "instance-name";
    String cpuSeries = "N1";
    // Number of CPU cores you want to use.
    int coreCount = 2;
    // The amount of memory for the VM instance, in megabytes.
    int memory = 256;

    createInstanceWithExtraMemoryWithoutHelper(projectId, zone, instanceName, cpuSeries, coreCount,
        memory);
  }

  // Create VM instances with extra memory without using a CustomMachineType class and
  // return the created Instance.
  public static void createInstanceWithExtraMemoryWithoutHelper(
      String project, String zone, String instanceName, String cpuSeries, int coreCount, int memory)
      throws IOException, ExecutionException, InterruptedException, TimeoutException {
    // Initialize client that will be used to send requests. This client only needs to be created
    // once, and can be reused for multiple requests. After completing all of your requests, call
    // the `instancesClient.close()` method on the client to safely
    // clean up any remaining background resources.
    try (InstancesClient instancesClient = InstancesClient.create()) {

      // The coreCount and memory values are not validated anywhere and can be rejected by the API.
      String machineType = String.format("zones/%s/machineTypes/%s-%s-%s-ext", zone, cpuSeries,
          coreCount, memory);

      AttachedDisk attachedDisk = AttachedDisk.newBuilder()
          .setInitializeParams(
              // Describe the size and source image of the boot disk to attach to the instance.
              // The list of public images available in Compute Engine can be found here:
              // https://cloud.google.com/compute/docs/images#list_of_public_images_available_on
              AttachedDiskInitializeParams.newBuilder()
                  .setSourceImage(
                      String.format("projects/%s/global/images/family/%s", "debian-cloud",
                          "debian-11"))
                  .setDiskSizeGb(10)
                  .build()
          )
          // Remember to set auto_delete to True if you want the disk to be deleted when you delete
          // your VM instance.
          .setAutoDelete(true)
          .setBoot(true)
          .build();

      // Create the Instance object with the relevant information.
      Instance instance = Instance.newBuilder()
          .setName(instanceName)
          .addDisks(attachedDisk)
          .setMachineType(machineType)
          .addNetworkInterfaces(
              NetworkInterface.newBuilder().setName("global/networks/default").build())
          .build();

      // Create the insert instance request object.
      InsertInstanceRequest insertInstanceRequest = InsertInstanceRequest.newBuilder()
          .setProject(project)
          .setZone(zone)
          .setInstanceResource(instance)
          .build();

      // Invoke the API with the request object and wait for the operation to complete.
      Operation response = instancesClient.insertAsync(insertInstanceRequest)
          .get(3, TimeUnit.MINUTES);

      // Check for errors.
      if (response.hasError()) {
        System.out.println("Instance creation failed!!" + response);
        return;
      }
      System.out.printf("Instance created : %s", instanceName);
      System.out.println("Operation Status: " + response.getStatus());
    }
  }
}

Node.js

이 샘플을 사용해 보기 전에 Compute Engine 빠른 시작: 클라이언트 라이브러리 사용Node.js 설정 안내를 따르세요. 자세한 내용은 Compute Engine Node.js API 참고 문서를 확인하세요.

Compute Engine에 인증하려면 애플리케이션 기본 사용자 인증 정보를 설정합니다. 자세한 내용은 로컬 개발 환경의 인증 설정을 참조하세요.

/**
 * TODO(developer): Uncomment and replace these variables before running the sample.
 */
// const projectId = 'YOUR_PROJECT_ID';
// const zone = 'europe-central2-b';
// const instanceName = 'YOUR_INSTANCE_NAME';
// const cpuSeries = 'N1';
// const coreCount = 2
// const memory = 256

// The coreCount and memory values are not validated anywhere and can be rejected by the API.

const compute = require('@google-cloud/compute');

async function createInstanceWithExtraMemWithoutHelper() {
  const instancesClient = new compute.InstancesClient();

  const machineType = `zones/${zone}/machineTypes/${cpuSeries}-${coreCount}-${memory}-ext`;

  const [response] = await instancesClient.insert({
    instanceResource: {
      name: instanceName,
      disks: [
        {
          initializeParams: {
            diskSizeGb: '64',
            sourceImage:
              'projects/debian-cloud/global/images/family/debian-11/',
          },
          autoDelete: true,
          boot: true,
        },
      ],
      machineType,
      networkInterfaces: [
        {
          name: 'global/networks/default',
        },
      ],
    },
    project: projectId,
    zone,
  });
  let operation = response.latestResponse;
  const operationsClient = new compute.ZoneOperationsClient();

  // Wait for the create operation to complete.
  while (operation.status !== 'DONE') {
    [operation] = await operationsClient.wait({
      operation: operation.name,
      project: projectId,
      zone: operation.zone.split('/').pop(),
    });
  }

  console.log('Instance created.');
}

createInstanceWithExtraMemWithoutHelper();

Python

이 샘플을 사용해 보기 전에 Compute Engine 빠른 시작: 클라이언트 라이브러리 사용Python 설정 안내를 따르세요. 자세한 내용은 Compute Engine Python API 참고 문서를 확인하세요.

Compute Engine에 인증하려면 애플리케이션 기본 사용자 인증 정보를 설정합니다. 자세한 내용은 로컬 개발 환경의 인증 설정을 참조하세요.

from __future__ import annotations

import re
import sys
from typing import Any
import warnings

from google.api_core.extended_operation import ExtendedOperation
from google.cloud import compute_v1


def get_image_from_family(project: str, family: str) -> compute_v1.Image:
    """
    Retrieve the newest image that is part of a given family in a project.

    Args:
        project: project ID or project number of the Cloud project you want to get image from.
        family: name of the image family you want to get image from.

    Returns:
        An Image object.
    """
    image_client = compute_v1.ImagesClient()
    # List of public operating system (OS) images: https://cloud.google.com/compute/docs/images/os-details
    newest_image = image_client.get_from_family(project=project, family=family)
    return newest_image


def disk_from_image(
    disk_type: str,
    disk_size_gb: int,
    boot: bool,
    source_image: str,
    auto_delete: bool = True,
) -> compute_v1.AttachedDisk:
    """
    Create an AttachedDisk object to be used in VM instance creation. Uses an image as the
    source for the new disk.

    Args:
         disk_type: the type of disk you want to create. This value uses the following format:
            "zones/{zone}/diskTypes/(pd-standard|pd-ssd|pd-balanced|pd-extreme)".
            For example: "zones/us-west3-b/diskTypes/pd-ssd"
        disk_size_gb: size of the new disk in gigabytes
        boot: boolean flag indicating whether this disk should be used as a boot disk of an instance
        source_image: source image to use when creating this disk. You must have read access to this disk. This can be one
            of the publicly available images or an image from one of your projects.
            This value uses the following format: "projects/{project_name}/global/images/{image_name}"
        auto_delete: boolean flag indicating whether this disk should be deleted with the VM that uses it

    Returns:
        AttachedDisk object configured to be created using the specified image.
    """
    boot_disk = compute_v1.AttachedDisk()
    initialize_params = compute_v1.AttachedDiskInitializeParams()
    initialize_params.source_image = source_image
    initialize_params.disk_size_gb = disk_size_gb
    initialize_params.disk_type = disk_type
    boot_disk.initialize_params = initialize_params
    # Remember to set auto_delete to True if you want the disk to be deleted when you delete
    # your VM instance.
    boot_disk.auto_delete = auto_delete
    boot_disk.boot = boot
    return boot_disk


def wait_for_extended_operation(
    operation: ExtendedOperation, verbose_name: str = "operation", timeout: int = 300
) -> Any:
    """
    Waits for the extended (long-running) operation to complete.

    If the operation is successful, it will return its result.
    If the operation ends with an error, an exception will be raised.
    If there were any warnings during the execution of the operation
    they will be printed to sys.stderr.

    Args:
        operation: a long-running operation you want to wait on.
        verbose_name: (optional) a more verbose name of the operation,
            used only during error and warning reporting.
        timeout: how long (in seconds) to wait for operation to finish.
            If None, wait indefinitely.

    Returns:
        Whatever the operation.result() returns.

    Raises:
        This method will raise the exception received from `operation.exception()`
        or RuntimeError if there is no exception set, but there is an `error_code`
        set for the `operation`.

        In case of an operation taking longer than `timeout` seconds to complete,
        a `concurrent.futures.TimeoutError` will be raised.
    """
    result = operation.result(timeout=timeout)

    if operation.error_code:
        print(
            f"Error during {verbose_name}: [Code: {operation.error_code}]: {operation.error_message}",
            file=sys.stderr,
            flush=True,
        )
        print(f"Operation ID: {operation.name}", file=sys.stderr, flush=True)
        raise operation.exception() or RuntimeError(operation.error_message)

    if operation.warnings:
        print(f"Warnings during {verbose_name}:\n", file=sys.stderr, flush=True)
        for warning in operation.warnings:
            print(f" - {warning.code}: {warning.message}", file=sys.stderr, flush=True)

    return result


def create_instance(
    project_id: str,
    zone: str,
    instance_name: str,
    disks: list[compute_v1.AttachedDisk],
    machine_type: str = "n1-standard-1",
    network_link: str = "global/networks/default",
    subnetwork_link: str = None,
    internal_ip: str = None,
    external_access: bool = False,
    external_ipv4: str = None,
    accelerators: list[compute_v1.AcceleratorConfig] = None,
    preemptible: bool = False,
    spot: bool = False,
    instance_termination_action: str = "STOP",
    custom_hostname: str = None,
    delete_protection: bool = False,
) -> compute_v1.Instance:
    """
    Send an instance creation request to the Compute Engine API and wait for it to complete.

    Args:
        project_id: project ID or project number of the Cloud project you want to use.
        zone: name of the zone to create the instance in. For example: "us-west3-b"
        instance_name: name of the new virtual machine (VM) instance.
        disks: a list of compute_v1.AttachedDisk objects describing the disks
            you want to attach to your new instance.
        machine_type: machine type of the VM being created. This value uses the
            following format: "zones/{zone}/machineTypes/{type_name}".
            For example: "zones/europe-west3-c/machineTypes/f1-micro"
        network_link: name of the network you want the new instance to use.
            For example: "global/networks/default" represents the network
            named "default", which is created automatically for each project.
        subnetwork_link: name of the subnetwork you want the new instance to use.
            This value uses the following format:
            "regions/{region}/subnetworks/{subnetwork_name}"
        internal_ip: internal IP address you want to assign to the new instance.
            By default, a free address from the pool of available internal IP addresses of
            used subnet will be used.
        external_access: boolean flag indicating if the instance should have an external IPv4
            address assigned.
        external_ipv4: external IPv4 address to be assigned to this instance. If you specify
            an external IP address, it must live in the same region as the zone of the instance.
            This setting requires `external_access` to be set to True to work.
        accelerators: a list of AcceleratorConfig objects describing the accelerators that will
            be attached to the new instance.
        preemptible: boolean value indicating if the new instance should be preemptible
            or not. Preemptible VMs have been deprecated and you should now use Spot VMs.
        spot: boolean value indicating if the new instance should be a Spot VM or not.
        instance_termination_action: What action should be taken once a Spot VM is terminated.
            Possible values: "STOP", "DELETE"
        custom_hostname: Custom hostname of the new VM instance.
            Custom hostnames must conform to RFC 1035 requirements for valid hostnames.
        delete_protection: boolean value indicating if the new virtual machine should be
            protected against deletion or not.
    Returns:
        Instance object.
    """
    instance_client = compute_v1.InstancesClient()

    # Use the network interface provided in the network_link argument.
    network_interface = compute_v1.NetworkInterface()
    network_interface.network = network_link
    if subnetwork_link:
        network_interface.subnetwork = subnetwork_link

    if internal_ip:
        network_interface.network_i_p = internal_ip

    if external_access:
        access = compute_v1.AccessConfig()
        access.type_ = compute_v1.AccessConfig.Type.ONE_TO_ONE_NAT.name
        access.name = "External NAT"
        access.network_tier = access.NetworkTier.PREMIUM.name
        if external_ipv4:
            access.nat_i_p = external_ipv4
        network_interface.access_configs = [access]

    # Collect information into the Instance object.
    instance = compute_v1.Instance()
    instance.network_interfaces = [network_interface]
    instance.name = instance_name
    instance.disks = disks
    if re.match(r"^zones/[a-z\d\-]+/machineTypes/[a-z\d\-]+$", machine_type):
        instance.machine_type = machine_type
    else:
        instance.machine_type = f"zones/{zone}/machineTypes/{machine_type}"

    instance.scheduling = compute_v1.Scheduling()
    if accelerators:
        instance.guest_accelerators = accelerators
        instance.scheduling.on_host_maintenance = (
            compute_v1.Scheduling.OnHostMaintenance.TERMINATE.name
        )

    if preemptible:
        # Set the preemptible setting
        warnings.warn(
            "Preemptible VMs are being replaced by Spot VMs.", DeprecationWarning
        )
        instance.scheduling = compute_v1.Scheduling()
        instance.scheduling.preemptible = True

    if spot:
        # Set the Spot VM setting
        instance.scheduling.provisioning_model = (
            compute_v1.Scheduling.ProvisioningModel.SPOT.name
        )
        instance.scheduling.instance_termination_action = instance_termination_action

    if custom_hostname is not None:
        # Set the custom hostname for the instance
        instance.hostname = custom_hostname

    if delete_protection:
        # Set the delete protection bit
        instance.deletion_protection = True

    # Prepare the request to insert an instance.
    request = compute_v1.InsertInstanceRequest()
    request.zone = zone
    request.project = project_id
    request.instance_resource = instance

    # Wait for the create operation to complete.
    print(f"Creating the {instance_name} instance in {zone}...")

    operation = instance_client.insert(request=request)

    wait_for_extended_operation(operation, "instance creation")

    print(f"Instance {instance_name} created.")
    return instance_client.get(project=project_id, zone=zone, instance=instance_name)


def create_custom_instances_extra_mem(
    project_id: str, zone: str, instance_name: str, core_count: int, memory: int
) -> list[compute_v1.Instance]:
    """
    Create 3 new VM instances with extra memory without using a CustomMachineType helper class.

    Args:
        project_id: project ID or project number of the Cloud project you want to use.
        zone: name of the zone to create the instance in. For example: "us-west3-b"
        instance_name: name of the new virtual machine (VM) instance.
        core_count: number of CPU cores you want to use.
        memory: the amount of memory for the VM instance, in megabytes.

    Returns:
        List of Instance objects.
    """
    newest_debian = get_image_from_family(project="debian-cloud", family="debian-12")
    disk_type = f"zones/{zone}/diskTypes/pd-standard"
    disks = [disk_from_image(disk_type, 10, True, newest_debian.self_link)]
    # The core_count and memory values are not validated anywhere and can be rejected by the API.
    instances = [
        create_instance(
            project_id,
            zone,
            f"{instance_name}_n1_extra_mem",
            disks,
            f"zones/{zone}/machineTypes/custom-{core_count}-{memory}-ext",
        ),
        create_instance(
            project_id,
            zone,
            f"{instance_name}_n2_extra_mem",
            disks,
            f"zones/{zone}/machineTypes/n2-custom-{core_count}-{memory}-ext",
        ),
        create_instance(
            project_id,
            zone,
            f"{instance_name}_n2d_extra_mem",
            disks,
            f"zones/{zone}/machineTypes/n2d-custom-{core_count}-{memory}-ext",
        ),
    ]
    return instances

REST

instances.insert 메서드를 사용하여 커스텀 메모리로 인스턴스를 만드는 것처럼 인스턴스 만들기 요청을 생성합니다. machineType 값을 지정할 때 확장 메모리를 나타내는 -ext를 포함합니다.

  • 모든 커스텀 머신 유형에 -ext를 추가하여 메모리를 특정 머신 계열에 설명된 한도까지 확장합니다.
  • E2 공유 코어의 경우 micro, small 또는 medium을 지정합니다.
        zones/ZONE/machineTypes//MACHINE_TYPE-NUMBER_OF_CPUS-AMOUNT_OF_MEMORY-ext

다음을 바꿉니다.

  • ZONE: 머신 위치
  • MACHINE_TYPE: 머신 유형(예: N2 또는 E2 small)
  • NUMBER_OF_CPUS: vCPU 수
  • AMOUNT_OF_MEMORY_MB: 메모리 양(MB)

예를 들어 다음은 vCPU가 2개이고, 메모리가 20GB인 N2 머신 유형을 지정합니다. 메모리는 MB로 변환해야 합니다.

zones/ZONE/machineTypes/n2-custom-2-20480-ext

기존 VM 인스턴스에 확장 메모리 추가

기존 인스턴스에 메모리를 더 추가하려면 먼저 인스턴스를 중지해야 합니다. 인스턴스가 중지된 후 다음 단계를 완료하여 VM에 메모리를 추가합니다.

콘솔

  1. Google Cloud 콘솔에서 VM 인스턴스 페이지로 이동합니다.

    VM 인스턴스로 이동

  2. VM 목록에서 수정할 중지된 VM을 선택합니다.

  3. 페이지 상단의 수정을 클릭합니다.

  4. 머신 구성에서 범용을 선택합니다.

  5. 머신 유형 섹션에서 커스텀을 선택합니다.

  6. 원하는 vCPU 수를 선택합니다.

  7. 확장 메모리를 추가하려면 확장 메모리를 선택한 다음 원하는 메모리 양을 지정합니다.

  8. 변경사항을 저장합니다.

gcloud

gcloud compute instances stop 명령어를 사용하여 VM을 중지합니다. 그런 다음 --custom-memory--custom-extensions 옵션과 함께 gcloud compute instances set-machine-type 명령어를 사용하여 머신의 리소스를 수정합니다.

변경사항을 저장하고 VM을 다시 시작합니다.

Go

이 샘플을 사용해 보기 전에 Compute Engine 빠른 시작: 클라이언트 라이브러리 사용Go 설정 안내를 따르세요. 자세한 내용은 Compute Engine Go API 참고 문서를 확인하세요.

Compute Engine에 인증하려면 애플리케이션 기본 사용자 인증 정보를 설정합니다. 자세한 내용은 로컬 개발 환경의 인증 설정을 참조하세요.

import (
	"context"
	"fmt"
	"io"
	"strings"

	compute "cloud.google.com/go/compute/apiv1"
	computepb "cloud.google.com/go/compute/apiv1/computepb"
	"google.golang.org/protobuf/proto"
)

// modifyInstanceWithExtendedMemory sends an instance creation request
// to the Compute Engine API and waits for it to complete.
func modifyInstanceWithExtendedMemory(
	w io.Writer,
	projectID, zone, instanceName string,
	newMemory int,
) error {
	// projectID := "your_project_id"
	// zone := "europe-central2-b"
	// instanceName := "your_instance_name"
	// newMemory := 256 // the amount of memory for the VM instance, in megabytes.

	ctx := context.Background()
	instancesClient, err := compute.NewInstancesRESTClient(ctx)
	if err != nil {
		return fmt.Errorf("NewInstancesRESTClient: %w", err)
	}
	defer instancesClient.Close()

	reqInstance := &computepb.GetInstanceRequest{
		Project:  projectID,
		Zone:     zone,
		Instance: instanceName,
	}

	instance, err := instancesClient.Get(ctx, reqInstance)
	if err != nil {
		return fmt.Errorf("unable to get instance: %w", err)
	}

	containsString := func(s []string, str string) bool {
		for _, v := range s {
			if v == str {
				return true
			}
		}

		return false
	}

	if !(strings.Contains(instance.GetMachineType(), "machineTypes/n1-") ||
		strings.Contains(instance.GetMachineType(), "machineTypes/n2-") ||
		strings.Contains(instance.GetMachineType(), "machineTypes/n2d-")) {
		return fmt.Errorf("extra memory is available only for N1, N2 and N2D CPUs")
	}

	// Make sure that the machine is turned off
	if !containsString([]string{"TERMINATED", "STOPPED"}, instance.GetStatus()) {
		reqStop := &computepb.StopInstanceRequest{
			Project:  projectID,
			Zone:     zone,
			Instance: instanceName,
		}

		op, err := instancesClient.Stop(ctx, reqStop)
		if err != nil {
			return fmt.Errorf("unable to stop instance: %w", err)
		}

		if err = op.Wait(ctx); err != nil {
			return fmt.Errorf("unable to wait for the operation: %w", err)
		}
	}

	// Modify the machine definition, remember that extended memory
	// is available only for N1, N2 and N2D CPUs
	machineType := instance.GetMachineType()
	start := machineType[:strings.LastIndex(machineType, "-")]

	updateReq := &computepb.SetMachineTypeInstanceRequest{
		Project:  projectID,
		Zone:     zone,
		Instance: instanceName,
		InstancesSetMachineTypeRequestResource: &computepb.InstancesSetMachineTypeRequest{
			MachineType: proto.String(fmt.Sprintf("%s-%v-ext", start, newMemory)),
		},
	}
	op, err := instancesClient.SetMachineType(ctx, updateReq)
	if err != nil {
		return fmt.Errorf("unable to update instance: %w", err)
	}

	if err = op.Wait(ctx); err != nil {
		return fmt.Errorf("unable to wait for the operation: %w", err)
	}

	fmt.Fprintf(w, "Instance updated\n")

	return nil

}

자바

이 샘플을 사용해 보기 전에 Compute Engine 빠른 시작: 클라이언트 라이브러리 사용Java 설정 안내를 따르세요. 자세한 내용은 Compute Engine Java API 참고 문서를 확인하세요.

Compute Engine에 인증하려면 애플리케이션 기본 사용자 인증 정보를 설정합니다. 자세한 내용은 로컬 개발 환경의 인증 설정을 참조하세요.


import com.google.api.gax.longrunning.OperationFuture;
import com.google.cloud.compute.v1.GetInstanceRequest;
import com.google.cloud.compute.v1.Instance;
import com.google.cloud.compute.v1.Instance.Status;
import com.google.cloud.compute.v1.InstancesClient;
import com.google.cloud.compute.v1.InstancesSetMachineTypeRequest;
import com.google.cloud.compute.v1.Operation;
import com.google.cloud.compute.v1.SetMachineTypeInstanceRequest;
import com.google.cloud.compute.v1.StopInstanceRequest;
import java.io.IOException;
import java.util.concurrent.ExecutionException;
import java.util.concurrent.TimeUnit;
import java.util.concurrent.TimeoutException;

public class UpdateMemory {

  public static void main(String[] args)
      throws IOException, ExecutionException, InterruptedException, TimeoutException {
    // TODO(developer): Replace these variables before running the sample.
    // Project ID or project number of the Cloud project you want to use.
    String projectId = "your-google-cloud-project-id";
    // Name of the zone to create the instance in. For example: "us-west3-b".
    String zone = "google-cloud-zone";
    // Name of the new virtual machine (VM) instance.
    String instanceName = "instance-name";
    // The amount of memory for the VM instance, in megabytes.
    int newMemory = 256;

    modifyInstanceWithExtendedMemory(projectId, zone, instanceName, newMemory);
  }

  // Modify an existing VM to use extended memory and return the modified Instance.
  public static void modifyInstanceWithExtendedMemory(
      String project, String zone, String instanceName, int newMemory)
      throws IOException, ExecutionException, InterruptedException, TimeoutException {
    // Initialize client that will be used to send requests. This client only needs to be created
    // once, and can be reused for multiple requests. After completing all of your requests, call
    // the `instancesClient.close()` method on the client to safely
    // clean up any remaining background resources.
    try (InstancesClient instancesClient = InstancesClient.create()) {

      // Create the get instance request object.
      GetInstanceRequest getInstanceRequest = GetInstanceRequest.newBuilder()
          .setProject(project)
          .setZone(zone)
          .setInstance(instanceName)
          .build();

      Instance instance = instancesClient.get(getInstanceRequest);

      // Check the machine type.
      if (!(instance.getMachineType().contains("machineTypes/n1-")
          || instance.getMachineType().contains("machineTypes/n2-")
          || instance.getMachineType().contains("machineTypes/n2d-"))) {
        System.out.println("extra memory is available only for N1, N2 and N2D CPUs");
        return;
      }

      // Make sure that the machine is turned off.
      if (!(instance.getStatus().equals(Status.TERMINATED.toString())
          || instance.getStatus().equals(Status.STOPPED.toString()))) {

        StopInstanceRequest stopInstanceRequest = StopInstanceRequest.newBuilder()
            .setProject(project)
            .setZone(zone)
            .setInstance(instanceName)
            .build();

        OperationFuture<Operation, Operation> operation = instancesClient.stopAsync(
            stopInstanceRequest);
        Operation response = operation.get(3, TimeUnit.MINUTES);
        if (response.hasError()) {
          System.out.printf("Unable to stop instance %s", response.getError());
          return;
        }
      }

      // Modify the machine definition. Note that extended memory
      // is available only for N1, N2 and N2D CPUs.
      String machineType = instance.getMachineType();
      String start = machineType.substring(0, machineType.lastIndexOf("-"));

      // Create the machine type instance request object.
      SetMachineTypeInstanceRequest setMachineTypeInstanceRequest =
          SetMachineTypeInstanceRequest.newBuilder()
              .setProject(project)
              .setZone(zone)
              .setInstance(instanceName)
              .setInstancesSetMachineTypeRequestResource(InstancesSetMachineTypeRequest.newBuilder()
                  .setMachineType(String.format("%s-%d-ext", start, newMemory))
                  .build())
              .build();

      // Invoke the API with the request object and wait for the operation to complete.
      Operation response = instancesClient.setMachineTypeAsync(setMachineTypeInstanceRequest)
          .get(3, TimeUnit.MINUTES);

      // Check for errors.
      if (response.hasError()) {
        System.out.printf("Unable to update instance %s", response.getError());
        return;
      }
      System.out.println("Instance updated!");
    }
  }
}

Node.js

이 샘플을 사용해 보기 전에 Compute Engine 빠른 시작: 클라이언트 라이브러리 사용Node.js 설정 안내를 따르세요. 자세한 내용은 Compute Engine Node.js API 참고 문서를 확인하세요.

Compute Engine에 인증하려면 애플리케이션 기본 사용자 인증 정보를 설정합니다. 자세한 내용은 로컬 개발 환경의 인증 설정을 참조하세요.

/**
 * TODO(developer): Uncomment and replace these variables before running the sample.
 */
// const projectId = 'YOUR_PROJECT_ID';
// const zone = 'europe-central2-b';
// const instanceName = 'YOUR_INSTANCE_NAME';
// const newMemory = 256;

const compute = require('@google-cloud/compute');

async function modifyInstanceWithExtendedMemory() {
  const instancesClient = new compute.InstancesClient();

  const [instance] = await instancesClient.get({
    project: projectId,
    zone,
    instance: instanceName,
  });

  if (
    !['machineTypes/n1-', 'machineTypes/n2-', 'machineTypes/n2d-'].some(
      type => instance.machineType.includes(type)
    )
  ) {
    throw new Error('extra memory is available only for N1, N2 and N2D CPUs');
  }

  // Make sure that the machine is turned off
  if (!['TERMINATED', 'STOPPED'].some(status => instance.status === status)) {
    const [response] = await instancesClient.stop({
      project: projectId,
      zone,
      instance: instanceName,
    });

    let operation = response.latestResponse;
    const operationsClient = new compute.ZoneOperationsClient();

    // Wait for the stop operation to complete.
    while (operation.status !== 'DONE') {
      [operation] = await operationsClient.wait({
        operation: operation.name,
        project: projectId,
        zone: operation.zone.split('/').pop(),
      });
    }
  }

  // Modify the machine definition, remember that extended memory
  // is available only for N1, N2 and N2D CPUs

  const start = instance.machineType.substring(
    0,
    instance.machineType.lastIndexOf('-')
  );

  const [response] = await instancesClient.setMachineType({
    project: projectId,
    zone,
    instance: instanceName,
    instancesSetMachineTypeRequestResource: {
      machineType: `${start}-${newMemory}-ext`,
    },
  });
  let operation = response.latestResponse;
  const operationsClient = new compute.ZoneOperationsClient();

  // Wait for the update operation to complete.
  while (operation.status !== 'DONE') {
    [operation] = await operationsClient.wait({
      operation: operation.name,
      project: projectId,
      zone: operation.zone.split('/').pop(),
    });
  }

  console.log('Instance updated.');
}

modifyInstanceWithExtendedMemory();

Python

이 샘플을 사용해 보기 전에 Compute Engine 빠른 시작: 클라이언트 라이브러리 사용Python 설정 안내를 따르세요. 자세한 내용은 Compute Engine Python API 참고 문서를 확인하세요.

Compute Engine에 인증하려면 애플리케이션 기본 사용자 인증 정보를 설정합니다. 자세한 내용은 로컬 개발 환경의 인증 설정을 참조하세요.

from __future__ import annotations

import sys
import time
from typing import Any

from google.api_core.extended_operation import ExtendedOperation
from google.cloud import compute_v1


def wait_for_extended_operation(
    operation: ExtendedOperation, verbose_name: str = "operation", timeout: int = 300
) -> Any:
    """
    Waits for the extended (long-running) operation to complete.

    If the operation is successful, it will return its result.
    If the operation ends with an error, an exception will be raised.
    If there were any warnings during the execution of the operation
    they will be printed to sys.stderr.

    Args:
        operation: a long-running operation you want to wait on.
        verbose_name: (optional) a more verbose name of the operation,
            used only during error and warning reporting.
        timeout: how long (in seconds) to wait for operation to finish.
            If None, wait indefinitely.

    Returns:
        Whatever the operation.result() returns.

    Raises:
        This method will raise the exception received from `operation.exception()`
        or RuntimeError if there is no exception set, but there is an `error_code`
        set for the `operation`.

        In case of an operation taking longer than `timeout` seconds to complete,
        a `concurrent.futures.TimeoutError` will be raised.
    """
    result = operation.result(timeout=timeout)

    if operation.error_code:
        print(
            f"Error during {verbose_name}: [Code: {operation.error_code}]: {operation.error_message}",
            file=sys.stderr,
            flush=True,
        )
        print(f"Operation ID: {operation.name}", file=sys.stderr, flush=True)
        raise operation.exception() or RuntimeError(operation.error_message)

    if operation.warnings:
        print(f"Warnings during {verbose_name}:\n", file=sys.stderr, flush=True)
        for warning in operation.warnings:
            print(f" - {warning.code}: {warning.message}", file=sys.stderr, flush=True)

    return result


def add_extended_memory_to_instance(
    project_id: str, zone: str, instance_name: str, new_memory: int
):
    """
    Modify an existing VM to use extended memory.

    Args:
        project_id: project ID or project number of the Cloud project you want to use.
        zone: name of the zone to create the instance in. For example: "us-west3-b"
        instance_name: name of the new virtual machine (VM) instance.
        new_memory: the amount of memory for the VM instance, in megabytes.

    Returns:
        Instance object.
    """
    instance_client = compute_v1.InstancesClient()
    instance = instance_client.get(
        project=project_id, zone=zone, instance=instance_name
    )

    if not (
        "n1-" in instance.machine_type
        or "n2-" in instance.machine_type
        or "n2d-" in instance.machine_type
    ):
        raise RuntimeError("Extra memory is available only for N1, N2 and N2D CPUs.")

    # Make sure that the machine is turned off
    if instance.status not in (
        instance.Status.TERMINATED.name,
        instance.Status.STOPPED.name,
    ):
        operation = instance_client.stop(
            project=project_id, zone=zone, instance=instance_name
        )
        wait_for_extended_operation(operation, "instance stopping")
        start = time.time()
        while instance.status not in (
            instance.Status.TERMINATED.name,
            instance.Status.STOPPED.name,
        ):
            # Waiting for the instance to be turned off.
            instance = instance_client.get(
                project=project_id, zone=zone, instance=instance_name
            )
            time.sleep(2)
            if time.time() - start >= 300:  # 5 minutes
                raise TimeoutError()

    # Modify the machine definition, remember that extended memory is available only for N1, N2 and N2D CPUs
    start, end = instance.machine_type.rsplit("-", maxsplit=1)
    instance.machine_type = start + f"-{new_memory}-ext"
    # TODO: If you prefer to use the CustomMachineType helper class, uncomment this code and comment the 2 lines above
    # Using CustomMachineType helper
    # cmt = CustomMachineType.from_str(instance.machine_type)
    # cmt.memory_mb = new_memory
    # cmt.extra_memory_used = True
    # instance.machine_type = str(cmt)
    operation = instance_client.update(
        project=project_id,
        zone=zone,
        instance=instance_name,
        instance_resource=instance,
    )
    wait_for_extended_operation(operation, "instance update")

    return instance_client.get(project=project_id, zone=zone, instance=instance_name)

REST

instances.stop 메서드를 사용한 다음 instances.setMachineType 메서드를 사용하여 머신 유형 리소스를 수정합니다.

인스턴스를 중지한 후 변경사항을 적용하여 machineTypes 옵션을 수정합니다.

{

'name': 'INSTANCE_NAME', 'machineType': 'zones/ZONE/machineTypes/MACHINE_TYPE',

... }

다음을 바꿉니다.

+ INSTANCE_NAME: The name of the VM
+ ZONE: The zone where your VMs reside
+ MACHINE_TYPE: The name of the VM

다음 단계