Tunnels and encapsulation
Magic WAN uses Generic Routing Encapsulation (GRE) and IPsec tunnels to transmit packets from Cloudflare’s global network to your origin network. Cloudflare sets up tunnel endpoints on global network servers inside your network namespace, and you set up tunnel endpoints on routers at your data center.
To accommodate additional header data introduced by encapsulation, the maximum segment size (MSS) must be adjusted so that packets comply with the standard Internet routable maximum transmission unit (MTU), which is 1500 bytes.
For instructions, refer to Set Maximum Segment Size.
This diagram illustrates the flow of traffic with Magic WAN.
Anycast tunnels
Magic WAN uses Anycast IP addresses for Cloudflare’s tunnel endpoints. In the Anycast model, any server in any data center can receive traffic and must be capable of encapsulating and decapsulating packets for any tunnel.
This works with GRE tunnels because the GRE protocol is stateless. Each packet is processed independently and does not require any negotiation or coordination between tunnel endpoints. Tunnel endpoints are technically bound to IP addresses but do not need to be bound to specific devices. Any device that can strip off the outer headers and then route the inner packet can handle any GRE packet sent over the tunnel.
For IPsec tunnels, the customer’s router negotiates the creation of an IPsec tunnel with Cloudflare using the Internet Key Exchange (IKE) protocol. Next, the Cloudflare server that handled that negotiation will propagate the details of that newly created IPsec tunnel (traffic selectors, keys, etc.) across Cloudflare’s data centers. The result is that any Cloudflare server can then handle traffic for that IPsec tunnel, even though only one Cloudflare server actually negotiated the setup of that tunnel.
Cloudflare’s Anycast architecture provides a conduit to your tunnel for every server in every data center on Cloudflare’s global network as shown in the image below.
IPsec tunnels
IPsec is a group of protocols that are used together to set up encrypted connections between devices. It helps keep data sent over public networks secure. IPsec is often used to set up VPNs, and it works by encrypting IP packets, along with authenticating the source where the packets come from.
For information on how to set up an IPsec tunnel, refer to Configure tunnel endpoints. To learn more about the configuration parameters Magic WAN uses to create an IPsec tunnel, keep reading.
How IKEv2 is used to establish an IPsec tunnel
Magic WAN uses the following stages to establish an IPsec tunnel:
- Initial Exchange (
IKE_SA_INIT
): IKE peers negotiate parameters for the IKE Security Association (SA) and establish a shared secret used for key derivation. After this exchange, the peers have a secure communication channel but they have not yet authenticated each other. If supported, the peers will also perform NAT detection in this exchange. - Auth Exchange (
IKE_AUTH
): Using the secure tunnel established in the initial exchange, IKE peers mutually authenticate each other. After authentication, the IKE security association (SA) is established. Next, the peers negotiate and establish an IPsec tunnel, known as a Child SA.
In summary, an IKE SA is created that uses certain cryptographic transforms. That IKE SA is then used to create a Child SA which itself uses certain cryptographic transforms. The configuration section below details which of these transforms for IKE SAs and Child SAs are currently supported by Magic WAN.
Supported configuration parameters
IKE SA
This is sometimes referred to as Phase 1 as per IKEv1 language.
Encryption
- AES-GCM-16 with 128-bit or 256-bit key length
- AES-CBC with 256-bit key length
Integrity (sometimes referred to as Authentication)
- SHA2-256
Diffie-Hellman group:
- DH group 14 (2048-bit MODP group)
- DH group 5 (1536-bit MODP group)
Pseudorandom function (PRF) (not to be confused with PFS. PRF is often not a configurable setting.)
- SHA2-256
- SHA2-384
- SHA2-512
IPsec
The Child SA. Sometimes referred to as Phase 2 as per IKEv1 language.
Encryption:
- AES-GCM-16 with 128-bit or 256-bit key length
- AES-CBC with 128-bit or 256-bit key length
Integrity (sometimes referred to as Authentication.)
- SHA2-256
- SHA-1
PFS group (sometimes referred to as Phase 2 Diffie-Hellman Group. Not to be confused with PRF.)
- DH group 14 (2048-bit MODP group)
- DH group 5 (1536-bit MODP group)
Required configuration parameters
- The IKE version must be IKEv2.
- The IKE authentication method must be Pre-Shared Key (PSK).
- Anti-replay protection must be disabled.
- If your router is behind NAT and requires NAT traversal (NAT-T), then your router must initiate IKE communication on port
4500
. Most devices support configuring NAT-T to begin on port4500
(exceptions include at least some versions of the Cisco ASA). NAT-T is not supported for IKE sessions which begin on port500
and then switch to port4500
. - (Uncommon) Extended Sequence Numbers (ESN) must be disabled.
Optional configuration parameters
- Null encryption for IPsec: This option should not be used unless necessary as it reduces security because IPsec traffic is not encrypted. You must explicitly opt in to use this option.
Supported IKE ID formats
Magic WAN supports the following IKE ID types for IPsec:
RFC name | Format | Example |
---|---|---|
ID_RFC822_ADDR | ipsec@<TUNNEL_ID>.<ACCOUNT_ID>.ipsec.cloudflare.com | ipsec@f5407d8db1a542b196c59f6d04ba8bd1.123456789.ipsec.cloudflare.com |
ID_FQDN | <TUNNEL_ID>.<ACCOUNT_ID>.ipsec.cloudflare.com | f5407d8db1a542b196c59f6d04ba8bd1.123456789.ipsec.cloudflare.com |
ID_KEY_ID | <ACCOUNT_ID>_<TUNNEL_ID> | 123456789_f5407d8db1a542b196c59f6d04ba8bd1 |
Additionally, the IKE ID type of ID_IPV4_ADDR
is supported if the following two conditions are met:
- The IPsec tunnel’s
customer_endpoint
value is set. - The combination of
cloudflare_endpoint
andcustomer_endpoint
is unique among the customer’s IPsec tunnels.