equinix.metal.Vrf
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Use this resource to manage a VRF.
See the Virtual Routing and Forwarding documentation for product details and API reference material.
Example Usage
example 1
using System.Collections.Generic;
using System.Linq;
using Pulumi;
using Equinix = Pulumi.Equinix;
return await Deployment.RunAsync(() =>
{
var example = new Equinix.Metal.Project("example", new()
{
Name = "example",
});
var exampleVrf = new Equinix.Metal.Vrf("exampleVrf", new()
{
Description = "VRF with ASN 65000 and a pool of address space that includes 192.168.100.0/25",
Name = "example-vrf",
Metro = "da",
LocalAsn = 65000,
IpRanges = new[]
{
"192.168.100.0/25",
"192.168.200.0/25",
},
ProjectId = example.Id,
});
});
package main
import (
"github.com/equinix/pulumi-equinix/sdk/go/equinix/metal"
"github.com/pulumi/pulumi/sdk/v3/go/pulumi"
)
func main() {
pulumi.Run(func(ctx *pulumi.Context) error {
example, err := metal.NewProject(ctx, "example", &metal.ProjectArgs{
Name: pulumi.String("example"),
})
if err != nil {
return err
}
_, err = metal.NewVrf(ctx, "exampleVrf", &metal.VrfArgs{
Description: pulumi.String("VRF with ASN 65000 and a pool of address space that includes 192.168.100.0/25"),
Name: pulumi.String("example-vrf"),
Metro: pulumi.String("da"),
LocalAsn: pulumi.Int(65000),
IpRanges: pulumi.StringArray{
pulumi.String("192.168.100.0/25"),
pulumi.String("192.168.200.0/25"),
},
ProjectId: example.ID(),
})
if err != nil {
return err
}
return nil
})
}
package generated_program;
import com.pulumi.Context;
import com.pulumi.Pulumi;
import com.pulumi.core.Output;
import com.pulumi.equinix.metal.Project;
import com.pulumi.equinix.metal.ProjectArgs;
import com.pulumi.equinix.metal.Vrf;
import com.pulumi.equinix.metal.VrfArgs;
import java.util.List;
import java.util.ArrayList;
import java.util.Map;
import java.io.File;
import java.nio.file.Files;
import java.nio.file.Paths;
public class App {
public static void main(String[] args) {
Pulumi.run(App::stack);
}
public static void stack(Context ctx) {
var example = new Project("example", ProjectArgs.builder()
.name("example")
.build());
var exampleVrf = new Vrf("exampleVrf", VrfArgs.builder()
.description("VRF with ASN 65000 and a pool of address space that includes 192.168.100.0/25")
.name("example-vrf")
.metro("da")
.localAsn("65000")
.ipRanges(
"192.168.100.0/25",
"192.168.200.0/25")
.projectId(example.id())
.build());
}
}
import pulumi
import pulumi_equinix as equinix
example = equinix.metal.Project("example", name="example")
example_vrf = equinix.metal.Vrf("exampleVrf",
description="VRF with ASN 65000 and a pool of address space that includes 192.168.100.0/25",
name="example-vrf",
metro="da",
local_asn=65000,
ip_ranges=[
"192.168.100.0/25",
"192.168.200.0/25",
],
project_id=example.id)
import * as pulumi from "@pulumi/pulumi";
import * as equinix from "@equinix-labs/pulumi-equinix";
const example = new equinix.metal.Project("example", {name: "example"});
const exampleVrf = new equinix.metal.Vrf("exampleVrf", {
description: "VRF with ASN 65000 and a pool of address space that includes 192.168.100.0/25",
name: "example-vrf",
metro: "da",
localAsn: 65000,
ipRanges: [
"192.168.100.0/25",
"192.168.200.0/25",
],
projectId: example.id,
});
resources:
example:
type: equinix:metal:Project
properties:
name: example
exampleVrf:
type: equinix:metal:Vrf
name: example
properties:
description: VRF with ASN 65000 and a pool of address space that includes 192.168.100.0/25
name: example-vrf
metro: da
localAsn: '65000'
ipRanges:
- 192.168.100.0/25
- 192.168.200.0/25
projectId: ${example.id}
example 2
using System.Collections.Generic;
using System.Linq;
using Pulumi;
using Equinix = Pulumi.Equinix;
return await Deployment.RunAsync(() =>
{
var example = new Equinix.Metal.ReservedIpBlock("example", new()
{
Description = "Reserved IP block (192.168.100.0/29) taken from on of the ranges in the VRF's pool of address space.",
ProjectId = exampleEquinixMetalProject.Id,
Metro = exampleEquinixMetalVrf.Metro,
Type = "vrf",
VrfId = exampleEquinixMetalVrf.Id,
Cidr = 29,
Network = "192.168.100.0",
});
var exampleVlan = new Equinix.Metal.Vlan("exampleVlan", new()
{
Description = "A VLAN for Layer2 and Hybrid Metal devices",
Metro = exampleEquinixMetalVrf.Metro,
ProjectId = exampleEquinixMetalProject.Id,
});
var exampleGateway = new Equinix.Metal.Gateway("exampleGateway", new()
{
ProjectId = exampleEquinixMetalProject.Id,
VlanId = exampleVlan.Id,
IpReservationId = example.Id,
});
});
package main
import (
"github.com/equinix/pulumi-equinix/sdk/go/equinix/metal"
"github.com/pulumi/pulumi/sdk/v3/go/pulumi"
)
func main() {
pulumi.Run(func(ctx *pulumi.Context) error {
example, err := metal.NewReservedIpBlock(ctx, "example", &metal.ReservedIpBlockArgs{
Description: pulumi.String("Reserved IP block (192.168.100.0/29) taken from on of the ranges in the VRF's pool of address space."),
ProjectId: pulumi.Any(exampleEquinixMetalProject.Id),
Metro: pulumi.Any(exampleEquinixMetalVrf.Metro),
Type: pulumi.String("vrf"),
VrfId: pulumi.Any(exampleEquinixMetalVrf.Id),
Cidr: pulumi.Int(29),
Network: pulumi.String("192.168.100.0"),
})
if err != nil {
return err
}
exampleVlan, err := metal.NewVlan(ctx, "exampleVlan", &metal.VlanArgs{
Description: pulumi.String("A VLAN for Layer2 and Hybrid Metal devices"),
Metro: pulumi.Any(exampleEquinixMetalVrf.Metro),
ProjectId: pulumi.Any(exampleEquinixMetalProject.Id),
})
if err != nil {
return err
}
_, err = metal.NewGateway(ctx, "exampleGateway", &metal.GatewayArgs{
ProjectId: pulumi.Any(exampleEquinixMetalProject.Id),
VlanId: exampleVlan.ID(),
IpReservationId: example.ID(),
})
if err != nil {
return err
}
return nil
})
}
package generated_program;
import com.pulumi.Context;
import com.pulumi.Pulumi;
import com.pulumi.core.Output;
import com.pulumi.equinix.metal.ReservedIpBlock;
import com.pulumi.equinix.metal.ReservedIpBlockArgs;
import com.pulumi.equinix.metal.Vlan;
import com.pulumi.equinix.metal.VlanArgs;
import com.pulumi.equinix.metal.Gateway;
import com.pulumi.equinix.metal.GatewayArgs;
import java.util.List;
import java.util.ArrayList;
import java.util.Map;
import java.io.File;
import java.nio.file.Files;
import java.nio.file.Paths;
public class App {
public static void main(String[] args) {
Pulumi.run(App::stack);
}
public static void stack(Context ctx) {
var example = new ReservedIpBlock("example", ReservedIpBlockArgs.builder()
.description("Reserved IP block (192.168.100.0/29) taken from on of the ranges in the VRF's pool of address space.")
.projectId(exampleEquinixMetalProject.id())
.metro(exampleEquinixMetalVrf.metro())
.type("vrf")
.vrfId(exampleEquinixMetalVrf.id())
.cidr(29)
.network("192.168.100.0")
.build());
var exampleVlan = new Vlan("exampleVlan", VlanArgs.builder()
.description("A VLAN for Layer2 and Hybrid Metal devices")
.metro(exampleEquinixMetalVrf.metro())
.projectId(exampleEquinixMetalProject.id())
.build());
var exampleGateway = new Gateway("exampleGateway", GatewayArgs.builder()
.projectId(exampleEquinixMetalProject.id())
.vlanId(exampleVlan.id())
.ipReservationId(example.id())
.build());
}
}
import pulumi
import pulumi_equinix as equinix
example = equinix.metal.ReservedIpBlock("example",
description="Reserved IP block (192.168.100.0/29) taken from on of the ranges in the VRF's pool of address space.",
project_id=example_equinix_metal_project["id"],
metro=example_equinix_metal_vrf["metro"],
type="vrf",
vrf_id=example_equinix_metal_vrf["id"],
cidr=29,
network="192.168.100.0")
example_vlan = equinix.metal.Vlan("exampleVlan",
description="A VLAN for Layer2 and Hybrid Metal devices",
metro=example_equinix_metal_vrf["metro"],
project_id=example_equinix_metal_project["id"])
example_gateway = equinix.metal.Gateway("exampleGateway",
project_id=example_equinix_metal_project["id"],
vlan_id=example_vlan.id,
ip_reservation_id=example.id)
import * as pulumi from "@pulumi/pulumi";
import * as equinix from "@equinix-labs/pulumi-equinix";
const example = new equinix.metal.ReservedIpBlock("example", {
description: "Reserved IP block (192.168.100.0/29) taken from on of the ranges in the VRF's pool of address space.",
projectId: exampleEquinixMetalProject.id,
metro: exampleEquinixMetalVrf.metro,
type: "vrf",
vrfId: exampleEquinixMetalVrf.id,
cidr: 29,
network: "192.168.100.0",
});
const exampleVlan = new equinix.metal.Vlan("exampleVlan", {
description: "A VLAN for Layer2 and Hybrid Metal devices",
metro: exampleEquinixMetalVrf.metro,
projectId: exampleEquinixMetalProject.id,
});
const exampleGateway = new equinix.metal.Gateway("exampleGateway", {
projectId: exampleEquinixMetalProject.id,
vlanId: exampleVlan.id,
ipReservationId: example.id,
});
resources:
example:
type: equinix:metal:ReservedIpBlock
properties:
description: Reserved IP block (192.168.100.0/29) taken from on of the ranges in the VRF's pool of address space.
projectId: ${exampleEquinixMetalProject.id}
metro: ${exampleEquinixMetalVrf.metro}
type: vrf
vrfId: ${exampleEquinixMetalVrf.id}
cidr: 29
network: 192.168.100.0
exampleVlan:
type: equinix:metal:Vlan
name: example
properties:
description: A VLAN for Layer2 and Hybrid Metal devices
metro: ${exampleEquinixMetalVrf.metro}
projectId: ${exampleEquinixMetalProject.id}
exampleGateway:
type: equinix:metal:Gateway
name: example
properties:
projectId: ${exampleEquinixMetalProject.id}
vlanId: ${exampleVlan.id}
ipReservationId: ${example.id}
example 3
using System.Collections.Generic;
using System.Linq;
using Pulumi;
using Equinix = Pulumi.Equinix;
return await Deployment.RunAsync(() =>
{
var exampleVirtualCircuit = new Equinix.Metal.VirtualCircuit("exampleVirtualCircuit", new()
{
Name = "example-vc",
Description = "Virtual Circuit",
ConnectionId = example.Id,
ProjectId = exampleEquinixMetalProject.Id,
PortId = example.Ports[0].Id,
NniVlan = 1024,
VrfId = exampleEquinixMetalVrf.Id,
PeerAsn = 65530,
Subnet = "192.168.100.16/31",
MetalIp = "192.168.100.16",
CustomerIp = "192.168.100.17",
});
});
package main
import (
"github.com/equinix/pulumi-equinix/sdk/go/equinix/metal"
"github.com/pulumi/pulumi/sdk/v3/go/pulumi"
)
func main() {
pulumi.Run(func(ctx *pulumi.Context) error {
_, err := metal.NewVirtualCircuit(ctx, "exampleVirtualCircuit", &metal.VirtualCircuitArgs{
Name: pulumi.String("example-vc"),
Description: pulumi.String("Virtual Circuit"),
ConnectionId: pulumi.Any(example.Id),
ProjectId: pulumi.Any(exampleEquinixMetalProject.Id),
PortId: pulumi.Any(example.Ports[0].Id),
NniVlan: pulumi.Int(1024),
VrfId: pulumi.Any(exampleEquinixMetalVrf.Id),
PeerAsn: pulumi.Int(65530),
Subnet: pulumi.String("192.168.100.16/31"),
MetalIp: pulumi.String("192.168.100.16"),
CustomerIp: pulumi.String("192.168.100.17"),
})
if err != nil {
return err
}
return nil
})
}
package generated_program;
import com.pulumi.Context;
import com.pulumi.Pulumi;
import com.pulumi.core.Output;
import com.pulumi.equinix.metal.VirtualCircuit;
import com.pulumi.equinix.metal.VirtualCircuitArgs;
import java.util.List;
import java.util.ArrayList;
import java.util.Map;
import java.io.File;
import java.nio.file.Files;
import java.nio.file.Paths;
public class App {
public static void main(String[] args) {
Pulumi.run(App::stack);
}
public static void stack(Context ctx) {
var exampleVirtualCircuit = new VirtualCircuit("exampleVirtualCircuit", VirtualCircuitArgs.builder()
.name("example-vc")
.description("Virtual Circuit")
.connectionId(example.id())
.projectId(exampleEquinixMetalProject.id())
.portId(example.ports()[0].id())
.nniVlan(1024)
.vrfId(exampleEquinixMetalVrf.id())
.peerAsn(65530)
.subnet("192.168.100.16/31")
.metalIp("192.168.100.16")
.customerIp("192.168.100.17")
.build());
}
}
import pulumi
import pulumi_equinix as equinix
example_virtual_circuit = equinix.metal.VirtualCircuit("exampleVirtualCircuit",
name="example-vc",
description="Virtual Circuit",
connection_id=example["id"],
project_id=example_equinix_metal_project["id"],
port_id=example["ports"][0]["id"],
nni_vlan=1024,
vrf_id=example_equinix_metal_vrf["id"],
peer_asn=65530,
subnet="192.168.100.16/31",
metal_ip="192.168.100.16",
customer_ip="192.168.100.17")
import * as pulumi from "@pulumi/pulumi";
import * as equinix from "@equinix-labs/pulumi-equinix";
const exampleVirtualCircuit = new equinix.metal.VirtualCircuit("exampleVirtualCircuit", {
name: "example-vc",
description: "Virtual Circuit",
connectionId: example.id,
projectId: exampleEquinixMetalProject.id,
portId: example.ports[0].id,
nniVlan: 1024,
vrfId: exampleEquinixMetalVrf.id,
peerAsn: 65530,
subnet: "192.168.100.16/31",
metalIp: "192.168.100.16",
customerIp: "192.168.100.17",
});
resources:
exampleVirtualCircuit:
type: equinix:metal:VirtualCircuit
name: example
properties:
name: example-vc
description: Virtual Circuit
connectionId: ${example.id}
projectId: ${exampleEquinixMetalProject.id}
portId: ${example.ports[0].id}
nniVlan: 1024
vrfId: ${exampleEquinixMetalVrf.id}
peerAsn: 65530
subnet: 192.168.100.16/31
metalIp: 192.168.100.16
customerIp: 192.168.100.17
variables:
example:
fn::invoke:
Function: equinix:metal:getInterconnection
Arguments:
connectionId: ${metalDedicatedConnectionId}
Create Vrf Resource
Resources are created with functions called constructors. To learn more about declaring and configuring resources, see Resources.
Constructor syntax
new Vrf(name: string, args: VrfArgs, opts?: CustomResourceOptions);
@overload
def Vrf(resource_name: str,
args: VrfArgs,
opts: Optional[ResourceOptions] = None)
@overload
def Vrf(resource_name: str,
opts: Optional[ResourceOptions] = None,
metro: Optional[str] = None,
project_id: Optional[str] = None,
description: Optional[str] = None,
ip_ranges: Optional[Sequence[str]] = None,
local_asn: Optional[int] = None,
name: Optional[str] = None)
func NewVrf(ctx *Context, name string, args VrfArgs, opts ...ResourceOption) (*Vrf, error)
public Vrf(string name, VrfArgs args, CustomResourceOptions? opts = null)
type: equinix:metal:Vrf
properties: # The arguments to resource properties.
options: # Bag of options to control resource's behavior.
Parameters
- name string
- The unique name of the resource.
- args VrfArgs
- The arguments to resource properties.
- opts CustomResourceOptions
- Bag of options to control resource's behavior.
- resource_name str
- The unique name of the resource.
- args VrfArgs
- The arguments to resource properties.
- opts ResourceOptions
- Bag of options to control resource's behavior.
- ctx Context
- Context object for the current deployment.
- name string
- The unique name of the resource.
- args VrfArgs
- The arguments to resource properties.
- opts ResourceOption
- Bag of options to control resource's behavior.
- name string
- The unique name of the resource.
- args VrfArgs
- The arguments to resource properties.
- opts CustomResourceOptions
- Bag of options to control resource's behavior.
- name String
- The unique name of the resource.
- args VrfArgs
- The arguments to resource properties.
- options CustomResourceOptions
- Bag of options to control resource's behavior.
Constructor example
The following reference example uses placeholder values for all input properties.
var vrfResource = new Equinix.Metal.Vrf("vrfResource", new()
{
Metro = "string",
ProjectId = "string",
Description = "string",
IpRanges = new[]
{
"string",
},
LocalAsn = 0,
Name = "string",
});
example, err := metal.NewVrf(ctx, "vrfResource", &metal.VrfArgs{
Metro: pulumi.String("string"),
ProjectId: pulumi.String("string"),
Description: pulumi.String("string"),
IpRanges: pulumi.StringArray{
pulumi.String("string"),
},
LocalAsn: pulumi.Int(0),
Name: pulumi.String("string"),
})
var vrfResource = new Vrf("vrfResource", VrfArgs.builder()
.metro("string")
.projectId("string")
.description("string")
.ipRanges("string")
.localAsn(0)
.name("string")
.build());
vrf_resource = equinix.metal.Vrf("vrfResource",
metro="string",
project_id="string",
description="string",
ip_ranges=["string"],
local_asn=0,
name="string")
const vrfResource = new equinix.metal.Vrf("vrfResource", {
metro: "string",
projectId: "string",
description: "string",
ipRanges: ["string"],
localAsn: 0,
name: "string",
});
type: equinix:metal:Vrf
properties:
description: string
ipRanges:
- string
localAsn: 0
metro: string
name: string
projectId: string
Vrf Resource Properties
To learn more about resource properties and how to use them, see Inputs and Outputs in the Architecture and Concepts docs.
Inputs
In Python, inputs that are objects can be passed either as argument classes or as dictionary literals.
The Vrf resource accepts the following input properties:
- Metro string
- Metro ID or Code where the VRF will be deployed
- Project
Id string - Project ID where the VRF will be deployed
- Description string
- Description of the VRF
- Ip
Ranges List<string> - All IPv4 and IPv6 Ranges that will be available to BGP Peers. IPv4 addresses must be /8 or smaller with a minimum size of /29. IPv6 must be /56 or smaller with a minimum size of /64. Ranges must not overlap other ranges within the VRF.
- Local
Asn int - The 4-byte ASN set on the VRF.
- Name string
- User-supplied name of the VRF, unique to the project
- Metro string
- Metro ID or Code where the VRF will be deployed
- Project
Id string - Project ID where the VRF will be deployed
- Description string
- Description of the VRF
- Ip
Ranges []string - All IPv4 and IPv6 Ranges that will be available to BGP Peers. IPv4 addresses must be /8 or smaller with a minimum size of /29. IPv6 must be /56 or smaller with a minimum size of /64. Ranges must not overlap other ranges within the VRF.
- Local
Asn int - The 4-byte ASN set on the VRF.
- Name string
- User-supplied name of the VRF, unique to the project
- metro String
- Metro ID or Code where the VRF will be deployed
- project
Id String - Project ID where the VRF will be deployed
- description String
- Description of the VRF
- ip
Ranges List<String> - All IPv4 and IPv6 Ranges that will be available to BGP Peers. IPv4 addresses must be /8 or smaller with a minimum size of /29. IPv6 must be /56 or smaller with a minimum size of /64. Ranges must not overlap other ranges within the VRF.
- local
Asn Integer - The 4-byte ASN set on the VRF.
- name String
- User-supplied name of the VRF, unique to the project
- metro string
- Metro ID or Code where the VRF will be deployed
- project
Id string - Project ID where the VRF will be deployed
- description string
- Description of the VRF
- ip
Ranges string[] - All IPv4 and IPv6 Ranges that will be available to BGP Peers. IPv4 addresses must be /8 or smaller with a minimum size of /29. IPv6 must be /56 or smaller with a minimum size of /64. Ranges must not overlap other ranges within the VRF.
- local
Asn number - The 4-byte ASN set on the VRF.
- name string
- User-supplied name of the VRF, unique to the project
- metro str
- Metro ID or Code where the VRF will be deployed
- project_
id str - Project ID where the VRF will be deployed
- description str
- Description of the VRF
- ip_
ranges Sequence[str] - All IPv4 and IPv6 Ranges that will be available to BGP Peers. IPv4 addresses must be /8 or smaller with a minimum size of /29. IPv6 must be /56 or smaller with a minimum size of /64. Ranges must not overlap other ranges within the VRF.
- local_
asn int - The 4-byte ASN set on the VRF.
- name str
- User-supplied name of the VRF, unique to the project
- metro String
- Metro ID or Code where the VRF will be deployed
- project
Id String - Project ID where the VRF will be deployed
- description String
- Description of the VRF
- ip
Ranges List<String> - All IPv4 and IPv6 Ranges that will be available to BGP Peers. IPv4 addresses must be /8 or smaller with a minimum size of /29. IPv6 must be /56 or smaller with a minimum size of /64. Ranges must not overlap other ranges within the VRF.
- local
Asn Number - The 4-byte ASN set on the VRF.
- name String
- User-supplied name of the VRF, unique to the project
Outputs
All input properties are implicitly available as output properties. Additionally, the Vrf resource produces the following output properties:
- Id string
- The provider-assigned unique ID for this managed resource.
- Id string
- The provider-assigned unique ID for this managed resource.
- id String
- The provider-assigned unique ID for this managed resource.
- id string
- The provider-assigned unique ID for this managed resource.
- id str
- The provider-assigned unique ID for this managed resource.
- id String
- The provider-assigned unique ID for this managed resource.
Look up Existing Vrf Resource
Get an existing Vrf resource’s state with the given name, ID, and optional extra properties used to qualify the lookup.
public static get(name: string, id: Input<ID>, state?: VrfState, opts?: CustomResourceOptions): Vrf
@staticmethod
def get(resource_name: str,
id: str,
opts: Optional[ResourceOptions] = None,
description: Optional[str] = None,
ip_ranges: Optional[Sequence[str]] = None,
local_asn: Optional[int] = None,
metro: Optional[str] = None,
name: Optional[str] = None,
project_id: Optional[str] = None) -> Vrf
func GetVrf(ctx *Context, name string, id IDInput, state *VrfState, opts ...ResourceOption) (*Vrf, error)
public static Vrf Get(string name, Input<string> id, VrfState? state, CustomResourceOptions? opts = null)
public static Vrf get(String name, Output<String> id, VrfState state, CustomResourceOptions options)
Resource lookup is not supported in YAML
- name
- The unique name of the resulting resource.
- id
- The unique provider ID of the resource to lookup.
- state
- Any extra arguments used during the lookup.
- opts
- A bag of options that control this resource's behavior.
- resource_name
- The unique name of the resulting resource.
- id
- The unique provider ID of the resource to lookup.
- name
- The unique name of the resulting resource.
- id
- The unique provider ID of the resource to lookup.
- state
- Any extra arguments used during the lookup.
- opts
- A bag of options that control this resource's behavior.
- name
- The unique name of the resulting resource.
- id
- The unique provider ID of the resource to lookup.
- state
- Any extra arguments used during the lookup.
- opts
- A bag of options that control this resource's behavior.
- name
- The unique name of the resulting resource.
- id
- The unique provider ID of the resource to lookup.
- state
- Any extra arguments used during the lookup.
- opts
- A bag of options that control this resource's behavior.
- Description string
- Description of the VRF
- Ip
Ranges List<string> - All IPv4 and IPv6 Ranges that will be available to BGP Peers. IPv4 addresses must be /8 or smaller with a minimum size of /29. IPv6 must be /56 or smaller with a minimum size of /64. Ranges must not overlap other ranges within the VRF.
- Local
Asn int - The 4-byte ASN set on the VRF.
- Metro string
- Metro ID or Code where the VRF will be deployed
- Name string
- User-supplied name of the VRF, unique to the project
- Project
Id string - Project ID where the VRF will be deployed
- Description string
- Description of the VRF
- Ip
Ranges []string - All IPv4 and IPv6 Ranges that will be available to BGP Peers. IPv4 addresses must be /8 or smaller with a minimum size of /29. IPv6 must be /56 or smaller with a minimum size of /64. Ranges must not overlap other ranges within the VRF.
- Local
Asn int - The 4-byte ASN set on the VRF.
- Metro string
- Metro ID or Code where the VRF will be deployed
- Name string
- User-supplied name of the VRF, unique to the project
- Project
Id string - Project ID where the VRF will be deployed
- description String
- Description of the VRF
- ip
Ranges List<String> - All IPv4 and IPv6 Ranges that will be available to BGP Peers. IPv4 addresses must be /8 or smaller with a minimum size of /29. IPv6 must be /56 or smaller with a minimum size of /64. Ranges must not overlap other ranges within the VRF.
- local
Asn Integer - The 4-byte ASN set on the VRF.
- metro String
- Metro ID or Code where the VRF will be deployed
- name String
- User-supplied name of the VRF, unique to the project
- project
Id String - Project ID where the VRF will be deployed
- description string
- Description of the VRF
- ip
Ranges string[] - All IPv4 and IPv6 Ranges that will be available to BGP Peers. IPv4 addresses must be /8 or smaller with a minimum size of /29. IPv6 must be /56 or smaller with a minimum size of /64. Ranges must not overlap other ranges within the VRF.
- local
Asn number - The 4-byte ASN set on the VRF.
- metro string
- Metro ID or Code where the VRF will be deployed
- name string
- User-supplied name of the VRF, unique to the project
- project
Id string - Project ID where the VRF will be deployed
- description str
- Description of the VRF
- ip_
ranges Sequence[str] - All IPv4 and IPv6 Ranges that will be available to BGP Peers. IPv4 addresses must be /8 or smaller with a minimum size of /29. IPv6 must be /56 or smaller with a minimum size of /64. Ranges must not overlap other ranges within the VRF.
- local_
asn int - The 4-byte ASN set on the VRF.
- metro str
- Metro ID or Code where the VRF will be deployed
- name str
- User-supplied name of the VRF, unique to the project
- project_
id str - Project ID where the VRF will be deployed
- description String
- Description of the VRF
- ip
Ranges List<String> - All IPv4 and IPv6 Ranges that will be available to BGP Peers. IPv4 addresses must be /8 or smaller with a minimum size of /29. IPv6 must be /56 or smaller with a minimum size of /64. Ranges must not overlap other ranges within the VRF.
- local
Asn Number - The 4-byte ASN set on the VRF.
- metro String
- Metro ID or Code where the VRF will be deployed
- name String
- User-supplied name of the VRF, unique to the project
- project
Id String - Project ID where the VRF will be deployed
Package Details
- Repository
- equinix equinix/pulumi-equinix
- License
- Apache-2.0
- Notes
- This Pulumi package is based on the
equinix
Terraform Provider.