info_tfgrid/collections/developers/go/grid3_go_vms.md

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2024-04-29 17:49:02 +00:00
<h1> Deploying Multiple VMs</h1>
<h2>Table of Contents</h2>
- [Introduction](#introduction)
- [Example](#example)
***
## Introduction
We show how to deploy multiple VMs with the Go client.
## Example
```go
import (
"context"
"fmt"
"net"
"github.com/threefoldtech/tfgrid-sdk-go/grid-client/deployer"
"github.com/threefoldtech/tfgrid-sdk-go/grid-client/workloads"
"github.com/threefoldtech/tfgrid-sdk-go/grid-proxy/pkg/types"
"github.com/threefoldtech/zos/pkg/gridtypes"
)
func main() {
// Create Threefold plugin client
tfPluginClient, err := deployer.NewTFPluginClient(mnemonics, "sr25519", network, "", "", "", 0, true)
// Get a free node to deploy
freeMRU := uint64(2)
freeSRU := uint64(2)
status := "up"
filter := types.NodeFilter {
FreeMRU: &freeMRU,
FreeSRU: &freeSRU,
Status: &status,
}
nodeIDs, err := deployer.FilterNodes(tfPluginClient.GridProxyClient, filter)
nodeID1 := uint32(nodeIDs[0].NodeID)
nodeID2 := uint32(nodeIDs[1].NodeID)
// Create a new network to deploy
network := workloads.ZNet{
Name: "newNetwork",
Description: "A network to deploy",
Nodes: []uint32{nodeID1, nodeID2},
IPRange: gridtypes.NewIPNet(net.IPNet{
IP: net.IPv4(10, 1, 0, 0),
Mask: net.CIDRMask(16, 32),
}),
AddWGAccess: true,
}
// Create new VMs to deploy
vm1 := workloads.VM{
Name: "vm1",
Flist: "https://hub.grid.tf/tf-official-apps/base:latest.flist",
CPU: 2,
PublicIP: true,
Planetary: true,
Memory: 1024,
RootfsSize: 20 * 1024,
Entrypoint: "/sbin/zinit init",
EnvVars: map[string]string{
"SSH_KEY": publicKey,
},
IP: "10.20.2.5",
NetworkName: network.Name,
}
vm2 := workloads.VM{
Name: "vm2",
Flist: "https://hub.grid.tf/tf-official-apps/base:latest.flist",
CPU: 2,
PublicIP: true,
Planetary: true,
Memory: 1024,
RootfsSize: 20 * 1024,
Entrypoint: "/sbin/zinit init",
EnvVars: map[string]string{
"SSH_KEY": publicKey,
},
IP: "10.20.2.6",
NetworkName: network.Name,
}
// Deploy the network first
err = tfPluginClient.NetworkDeployer.Deploy(ctx, &network)
// Load the network using the state loader
// this loader should load the deployment as json then convert it to a deployment go object with workloads inside it
networkObj, err := tfPluginClient.State.LoadNetworkFromGrid(network.Name)
// Deploy the VM deployments
dl1 := workloads.NewDeployment("vm1", nodeID1, "", nil, network.Name, nil, nil, []workloads.VM{vm1}, nil)
dl2 := workloads.NewDeployment("vm2", nodeID2, "", nil, network.Name, nil, nil, []workloads.VM{vm2}, nil)
err = tfPluginClient.DeploymentDeployer.BatchDeploy(ctx, []*workloads.Deployment{&dl1, &dl2})
// Load the VMs using the state loader
vmObj1, err := tfPluginClient.State.LoadVMFromGrid(nodeID1, vm1.Name, dl1.Name)
vmObj2, err := tfPluginClient.State.LoadVMFromGrid(nodeID2, vm2.Name, dl2.Name)
// Print the VMs Yggdrasil IP
fmt.Println(vmObj1.YggIP)
fmt.Println(vmObj2.YggIP)
// Cancel the VM deployments
err = tfPluginClient.DeploymentDeployer.Cancel(ctx, &dl1)
err = tfPluginClient.DeploymentDeployer.Cancel(ctx, &dl2)
// Cancel the network
err = tfPluginClient.NetworkDeployer.Cancel(ctx, &network)
}
```
Running this code should result in two VMs deployed on two separate nodes while being on the same network and you should see an output like this:
```bash
300:e9c4:9048:57cf:f4e0:2343:f891:6037
300:e9c4:9048:57cf:6d98:42c6:a7bf:2e3f
```