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vCloud Edge Gateway is a CLI tool and Ruby library that supports automated provisioning of a VMware vCloud Director Edge Gateway appliance

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vCloud Edge Gateway

vCloud Edge Gateway is a CLI tool and Ruby library that supports automated provisiong of a VMware vCloud Director Edge Gateway appliance. It depends on vCloud Core and uses Fog under the hood.

Installation

Add this line to your application's Gemfile:

gem 'vcloud-edge_gateway'

And then execute:

$ bundle

Or install it yourself as:

$ gem install vcloud-edge_gateway

Usage

To configure an Edge Gateway:

$ vcloud-edge-configure input.yaml

To use mustache templates so that rulesets can be re-used between environments:

$ vcloud-edge-configure --template-vars vars.yaml input.yaml.mustache

Credentials

Please see the vcloud-tools usage documentation.

Configure edge gateway services

You can configure the following services on an existing edgegateway using vcloud-edge-configure.

  • firewall_service
  • nat_service
  • load_balancer_service
  • gateway_ipsec_vpn_service
  • static_routing_service

The vcloud-edge-configure tool takes an input YAML file describing one or more of these services and updates the edge gateway configuration to match, obeying the following rules:

  • A given service will not be reconfigured if its input configuration matches the live configuration - to prevent unneccessary service reloads.
  • If a service is not defined in the input config, it will not be updated on the remote edge gateway - to permit per-service configurations.
  • If more than one service is defined and have changed, then all changed services will be updated in the same API request.

firewall_service

The edge gateway firewall service offers basic inbound and outbound IPv4 firewall rules, applied on top of a default policy.

We default to the global firewall policy being 'drop', and each individual rule to be 'allow'. Rules are applied in order, with the last match winning.

Each rule has the following form:

 - description: "Description of your rule"
   destination_port_range: "53"  # defaults to 'Any'
   destination_ip: "192.0.2.15"
   source_ip: "Any"
   source_port_range: "1024-65535"  # defaults to 'Any'
   protocol: 'udp' # defaults to 'tcp'
   policy: 'allow'  # defaults to 'drop'

Rule fields have the following behaviour

  • policy defaults to 'allow', can also be 'drop'.
  • protocol defaults to 'tcp'. Can be 'icmp', 'udp', 'tcp+udp' or 'any'
  • source_port_range and destination_port_range can be Any (default), a single port number (eg '443'), or a port range such as '10000-20000'
  • source_ip and destination_ip must be specified.
  • source_ip and destination_ip can be one of:
    • Any to match any address.
    • external, or internal to refer to addresses on the respective 'sides' of the edge gateway.
    • A single IP address, such as 192.0.2.44
    • A CIDR range, eg 192.0.2.0/24
    • A hyphened range, such as 192.0.2.50-192.0.2.60

nat_service

The edge gateway NAT service offers simple stateful Source-NAT and Destination-NAT rules.

SNAT rules take a source IP address range and 'Translated IP address'. The translated address is generally the public address that you wish traffic to appear to be coming from. SNAT rules are typically used to enable outbound connectivity from a private address range behind the edge. The UUID of the external network that the traffic should appear to come from must also be specified, as per the network_id field below.

A SNAT rule has the following form:

 - rule_type: 'SNAT'
   network_id: '12345678-1234-1234-1234-1234567890bb' # id of EdgeGateway external network
   original_ip: "10.10.10.0/24"  # internal IP range
   translated_ip: "192.0.2.100
  • original_ip can be a single IP address, a CIDR range, or a hyphenated IP range.
  • network_id must be the UUID of the network on which the translated_ip sits. Instructions are in the finding external network details section below.
  • translated_ip must be an available address on the network specified by network_id

DNAT rules translate packets addressed to a particular destination IP (and typically port) and translate it to an internal address - they are usually defined to allow external hosts to connect to services on hosts with private IP addresses.

A DNAT rule has the following form, and translates packets going to the original_ip (and original_port) to the translated_ip and translated_port values.

- rule_type: 'DNAT'
  network_id: '12345678-1234-1234-1234-1234567890bb' # id of EdgeGateway external network
  original_ip: "192.0.2.98" # Useable address on external network
  original_port: "22"       # external port
  translated_ip: "10.10.10.10"  # internal address to DNAT to
  translated_port: "22"
  • network_id specifies the UUID of the external network that packets are translated from.
  • original_ip is an IP address on the external network above.
  • protocol defaults to 'tcp'. Can be 'icmp', 'udp', 'tcpudp' or 'any'

load_balancer_service

The load balancer service comprises two sets of configurations: 'pools' and 'virtual_servers'. These are coupled together to form load balanced services:

  • A virtual_server provides the front-end of a load balancer - the port and IP that clients connect to.
  • A pool is a collection of one or more back-end nodes (IP+port combination) that traffic is balanced across.
  • Each virtual_server entry specifies a pool that serves requests destined to it.
  • Multiple virtual_servers can specify the same pool (to run the same service on different FQDNs, for example)
  • virtual_servers define any 'session persistence' information, if sessions are required to stick to the same pool member. (Session persistence is not currently supported by this tool.)
  • pools define 'member healthchecks', and so are aware of the health of their member nodes.

A typical load balancer configuration (for one service, mapping 192.0.2.0:80 to port 8080 on three servers) would look something like:

load_balancer_service:

  pools:
  - name: 'example-pool-1'
    description: 'A pool balancing traffic across backend nodes on port 8080'
    service:
      http:
        port: 8080
    members:
    - ip_address: 10.10.10.11
    - ip_address: 10.10.10.12
    - ip_address: 10.10.10.13

  virtual_servers:
  - name: 'example-virtual-server-1'
    description: 'A virtual server connecting to example-pool-1'
    ip_address: 192.0.2.10
    network: '12345678-1234-1234-1234-123456789012' # id of external network
    pool: 'example-pool-1' # must refer to a pool name detailed above
    service_profiles:
      http:  # protocol to balance, can be tcp/http/https.
        port: '80'  # external port

The vCloud Director load balancer service is quite basic, but supports the following:

  • Layer 7 balancing of HTTP traffic
  • Balancing of HTTPS traffic (though no decryption is possible, so this is purely level-4 based)
  • Layer 4 balancing of arbitrary TCP traffic.
  • URI-based healthchecks of backend nodes
  • Several balancing algorithms, such as 'round robin', and 'least connections'
  • Ability to persist sessions to the same backend member node, via a variety of means (eg HTTP cookie value, SSL session ID, source IP hash).

vcloud-edge-configure supports all of the above features.

It is also worth noting that the vCloud Director load balancer does not support:

  • In vCD 5.1, TCP and HTTPS layer-4 balancing are based on TCP port forwarding. There is no NAT in the mix, so the backend pools see the IP address/port of the edge rather than the remote host.
  • There is no SSL offloading/decryption possible on the device, so traffic inspection of HTTPS is not feasible.

Rather unusually, each virtual server and pool combination can handle traffic balancing for HTTP, HTTPS, and a single TCP port simultaneously. For example:

load_balancer_service:
  pools:
  - name: 'example-multi-protocol-pool-1'
    description: 'A pool balancing HTTP, HTTPS, and SMTP traffic'
    service:
      http: {}
      https: {}
      tcp:
        port: 25
    members:
    - ip_address: 10.10.10.14
    - ip_address: 10.10.10.15
  virtual_servers:
  - name: 'example-multi-protocol-virtual-server-1'
    description: 'A virtual server connecting to example-pool-1'
    ip_address: 192.0.2.11
    network: '12345678-1234-1234-1234-123456789012'
    pool: 'example-multi-protocol-pool-1'
    service_profiles:
      http: {}
      https: {}
      tcp:
        port: 25

The above is particularly useful for services that require balancing of HTTP and HTTPS traffic together.

load_balancer_service pool entries in detail

Each pool entry consists of:

  • a pool name, and optional description
  • a 'service' section - which protocol(s) to balance, and how to balance them.
  • a 'members' list - which backend nodes to use.

For example:

name: test-pool-1
description: Balances HTTP and HTTPS
service:
  http: {}
  https: {}
members:
- ip_address: 10.10.10.11
- ip_address: 10.10.10.12
  weight: 10

Here we have:

  • HTTP and HTTPS traffic balanced across 10.10.10.11 and 10.10.10.12.
  • member 10.10.10.11 has a default weight of 1
  • member 10.10.10.12 has a weight of 10, so will receive 10x the traffic of 10.10.10.11
  • http and https services are using all defaults, which means:
    • they use standard ports (80 for HTTP, 443 for HTTPS)
    • they will use 'round robin' balancing
    • HTTP service will 'GET /' from each node to check its health
    • HTTPS service will check 'SSL hello' response to confirm its health.

Service entries are the most complex, due to the available options on a per-service basis. The defaults we provide are suitable for most situations, but for more infomation see below.

A more complete HTTP service entry looks like:

service:
  http:
    port: 8080
    algorithm: 'ROUND_ROBIN'  # can also be 'LEAST_CONNECTED', 'IP_HASH', 'URI'
    health_check:
      port: 8081            # port to check health on, if not service port above.
      uri: /healthcheck     # for HTTP, the URI to check for 200/30* response
      protocol: HTTP        # the protocol to talk to health check service: HTTP, SSL, TCP
      health_threshold:  2  # how many checks to success before reenabling member
      unhealth_threshold: 3 # how many checks to fail before disabling member
      interval: 5           # interval between checks
      timeout: 15           # how long to wait before assuming healthcheck has failed

See the vCloud Director Admin Guide for more details on configuring Pool entries.

load_balancer_service virtual_server entries in detail

Each virtual_server entry must consist of:

  • a virtual_server name, and optional description
  • a 'service_profiles' section: which protocol(s) to handle
  • a network reference - the UUID of the network which the ip_address sits on.
  • a backend pool to use, referenced by name

For example:

name: test-virtual_server-1
description: Public facing side of test-pool-1
pool: test-pool-1
ip_address: 192.0.2.55  # front-end IP address, usually external
network: 12345678-1234-1234-1234-1234567890aa # UUID of network containing ip_address
service_profiles:
  http: { port: 8080 } # override default port 80
  https: { }  # port defaults to 443

Limited session persistence configurations can be defined in the virtual_server service_profiles section, if it is required that traffic 'stick' to the backend member that it originally was destined for. The available persistence mechanisms change based on which service is being handled:

For the 'http' service_profile, we can use Cookie based persistence:

  http:
    port: 8080
    persistence:
      method: COOKIE
      cookie_name: JSESSIONID # can be any cookie name string
      cookie_method: APP      # can be one of INSERT, PREFIX, or APP

For the 'https' service_profile, we can use SSL Session ID based persistence:

  https:
    port: 8443
    persistence:
      method: SSL_SESSION_ID

There is no persistence option for 'tcp' service_profiles.

See the vCloud Director Admin Guide for more details on configuring VirtualServer entries.

gateway_ipsec_vpn_service

The edge gateway VPN service allows setting up a basic IPSEC VPN peer. Configuration will depend on how the remote peer device is configured. Multiple tunnels can be configured, along with multiple local and remote peer subnets in a single tunnel.

The configuration requires several details:

  • Peer IP address: the public address of the remote peer
  • Local IP address: the public address of the local peer
  • Peer subnets: A private network address range which determines what traffic will traverse the tunnel
  • Local subnets: A private network address range which determines what traffic will be routed from the remote peer
  • Shared secret: This is the shared secret key which must be the same on both sides of the tunnel for encryption purposes
  • Encryption protocol: This should match on both sides of the tunnel
  • MTU: This sould match on both sides of the tunnel

Here is an example configuration:

---
gateway: GATEWAY_ID
gateway_ipsec_vpn_service:
  enabled: true
  tunnels:
  - :name: 'Example_name_without_spaces'
    :enabled: true
    :rule_type: 'DNAT'
    :description: 'Description name with spaces'
    :ipsec_vpn_local_peer:
      :id: 'this-is-an-example-edgegatewayid'
      :name: 'NameOfEdgeGateway'
    :peer_ip_address: 1.2.3.4
    :peer_id: '1.2.3.4'
    :local_ip_address: 4.3.2.1
    :local_id: '4.3.2.1'
    :peer_subnets:
      - :name: '172.16.0.0/24'
        :gateway: '172.16.0.1'
        :netmask: '255.255.255.0'
    :shared_secret: usesomethinglikea32characterpassword
    :encryption_protocol: 'AES'
    :mtu: 1500
    :local_subnets:
      - :name: '192.168.0.0/24'
        :gateway: '192.168.0.1'
        :netmask: '255.255.255.0'

static_routing_service

You can set up specific static routes using the vEdge Gateway. It allows you to route traffic that is destined to a specific destination IP to go via a specific gateway.

---
gateway: GATEWAY_ID
static_routing_service:
  static_routes:
  - enabled: true
    name: 'Example Static Route'
    network: '192.168.0.0/24'
    next_hop: '172.16.0.1'
    apply_on: EDGE_GATEWAY_EXT_NETWORK

Finding external network details from vcloud-walk

You can find the network UUID and external address allocations using vCloud Walker:

To do this, do:

export FOG_CREDENTIAL={crediental-tag-for-your-organization}
vcloud-walk edgegateways > edges.out

edges.out will contain the complete configuration of all edge gateways in your organization. Find the edge gateway you are interested in by searching for its name, then look for a GatewayInterface section that has an InterfaceType of 'uplink'. This should define:

  • a 'href' element in a Network section. The UUID at the end of this href is what you need.
  • an IpRange section with a StartAddress and EndAddress -- these define the addresses that you can use for services on this external network.

You can use jq to make this easier:

cat edges.out | jq '
  .[] | select(.name == "NAME_OF_YOUR_EDGE_GATEWAY")
      | .Configuration.GatewayInterfaces.GatewayInterface[]
      | select(.InterfaceType == "uplink")
      | ( .Network.href, .SubnetParticipation )
      '

Full configuration examples and schemas

Full configuration examples are in the examples/ folder.

Configuration schemas are in lib/vcloud/edge_gateway/schema/.

The vCloud API

vCloud Tools currently use version 5.1 of the vCloud API. Version 5.5 may work but is not currently supported. You should be able to access the 5.1 API in a 5.5 environment, and this is currently supported.

The default version is defined in Fog.

If you want to be sure you are pinning to 5.1, or use 5.5, you can set the API version to use in your fog file, e.g.

vcloud_director_api_version: 5.1

Debugging

export EXCON_DEBUG=true - this will print out the API requests and responses.

export DEBUG=true - this will show you the stack trace when there is an exception instead of just the message.

Testing

Run the default suite of tests (e.g. lint, unit, features):

bundle exec rake

There are also integration tests. These are slower and require a real environment. See the vCloud Tools website for details of how to set up and run the integration tests.

The parameters required to run the vCloud Edge Gateway integration tests are:

default:                # This is the fog credential that refers to your testing environment, e.g. `test_credential`
  network_1:            # Primary network name
  network_1_id:         # Primary network ID
  network_1_ip:         # Primary network IP
  edge_gateway:         # Edge gateway name
  provider_network:     # Provider (external-facing) network name
  provider_network_id:  # Provider network ID
  provider_network_ip:  # Provider network IP

References

Contributing

Please see CONTRIBUTING.md.

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vCloud Edge Gateway is a CLI tool and Ruby library that supports automated provisioning of a VMware vCloud Director Edge Gateway appliance

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