Oracle Cloud Infrastructure Documentation

Juniper SRX

This topic provides configuration for a Juniper SRX that is running software version JunOS 11.0 (or newer).

Important

Oracle provides configuration instructions for a tested set of vendors and devices. Use the correct configuration for your vendor and software version.

If the device or software version that Oracle used to verify the configuration does not exactly match your device or software, you might still be able to create the necessary configuration on your device. Consult your vendor's documentation and make any necessary adjustments.

If your device is for a vendor not in the list of verified vendors and devices, or if you're already familiar with configuring your device for IPSec, see the list of supported IPSec parameters and consult your vendor's documentation for assistance.

The following diagram shows a basic IPSec connection to Oracle Cloud Infrastructure with redundant tunnels. IP addresses used in this diagram are for example purposes only.

This image summarizes the general layout of your on-premises network, Site-to-Site VPN IPSec tunnels, and VCN.

Best Practices

This section covers general best practices and considerations for using Site-to-Site VPN.

Configure All Tunnels for Every IPSec Connection

Oracle deploys two IPSec headends for each of your connections to provide high availability for your mission-critical workloads. On the Oracle side, these two headends are on different routers for redundancy purposes. Oracle recommends configuring all available tunnels for maximum redundancy. This is a key part of the "Design for Failure" philosophy.

Have Redundant CPEs in Your On-Premises Network Locations

Each of your sites that connects with IPSec to Oracle Cloud Infrastructure should have redundant edge devices (also known as customer-premises equipment (CPE)). You add each CPE to the Oracle Console and create a separate IPSec connection between your dynamic routing gateway (DRG)  and each CPE. For each IPSec connection, Oracle provisions two tunnels on geographically redundant IPSec headends. For more information, see the Connectivity Redundancy Guide (PDF).

Routing Protocol Considerations

When you create a Site-to-Site VPN IPSec connection, it has two redundant IPSec tunnels. Oracle encourages you to configure your CPE to use both tunnels (if your CPE supports it). In the past, Oracle created IPSec connections that had up to four IPSec tunnels.

The following three routing types are available, and you choose the routing type separately for each tunnel in the Site-to-Site VPN:

  • BGP dynamic routing: The available routes are learned dynamically through BGP. The DRG dynamically learns the routes from your on-premises network. On the Oracle side, the DRG advertises the VCN's subnets.
  • Static routing: When you set up the IPSec connection to the DRG, you specify the particular routes to your on-premises network that you want the VCN to know about. You also must configure your CPE device with static routes to the VCN's subnets. These routes are not learned dynamically.
  • Policy-based routing: When you set up the IPSec connection to the DRG, you specify the particular routes to your on-premises network that you want the VCN to know about. You also must configure your CPE device with static routes to the VCN's subnets. These routes are not learned dynamically.

For more information about routing with Site-to-Site VPN, including Oracle recommendations on how to manipulate the BGP best path selection algorithm, see Routing for Site-to-Site VPN.

Other Important CPE Configurations

Ensure that access lists on your CPE are configured correctly to not block necessary traffic from or to Oracle Cloud Infrastructure.

If you have multiple tunnels up simultaneously, you might experience asymmetric routing. To allow for asymmetric routing, ensure that your CPE is configured to handle traffic coming from your VCN on any of the tunnels. For example, you need to disable ICMP inspection, configure TCP state bypass . For more details about the appropriate configuration, contact your CPE vendor's support. To configure routing to be symmetric, refer to Routing for Site-to-Site VPN.

Caveats and Limitations

This section covers general important characteristics and limitations of Site-to-Site VPN to be aware of. See Service Limits for a list of applicable limits and instructions for requesting a limit increase.

Asymmetric Routing

Oracle uses asymmetric routing across the multiple tunnels that make up the IPSec connection. Configure your firewalls accordingly. Otherwise, ping tests or application traffic across the connection don't work reliably.

When you use multiple tunnels to Oracle Cloud Infrastructure, Oracle recommends that you configure your routing to deterministically route traffic through the preferred tunnel. If you want to use one IPSec tunnel as primary and another as backup, configure more-specific routes for the primary tunnel (BGP) and less-specific routes (summary or default route) for the backup tunnel (BGP/static). Otherwise, if you advertise the same route (for example, a default route) through all tunnels, return traffic from your VCN to your on-premises network routes to any of the available tunnels. This is because Oracle uses asymmetric routing.

For specific Oracle routing recommendations about how to force symmetric routing, see Routing for Site-to-Site VPN.

Route-Based or Policy-Based Site-to-Site VPN

The IPSec protocol uses Security Associations (SAs) to determine how to encrypt packets. Within each SA, you define encryption domains to map a packet's source and destination IP address and protocol type to an entry in the SA database to define how to encrypt or decrypt a packet.

Note

Other vendors or industry documentation might use the term proxy ID, security parameter index (SPI), or traffic selector when referring to SAs or encryption domains.

There are two general methods for implementing IPSec tunnels:

  • Route-based tunnels: Also called next-hop-based tunnels. A route table lookup is performed on a packet's destination IP address. If that route's egress interface is an IPSec tunnel, the packet is encrypted and sent to the other end of the tunnel.
  • Policy-based tunnels: The packet's source and destination IP address and protocol are matched against a list of policy statements. If a match is found, the packet is encrypted based on the rules in that policy statement.

The Oracle Site-to-Site VPN headends use route-based tunnels but can work with policy-based tunnels with some caveats listed in the following sections.

Encryption domain for route-based tunnels

If your CPE supports route-based tunnels, use that method to configure the tunnel. It's the simplest configuration with the most interoperability with the Oracle VPN headend.

Route-based IPSec uses an encryption domain with the following values:

  • Source IP address: Any (0.0.0.0/0)
  • Destination IP address: Any (0.0.0.0/0)
  • Protocol: IPv4

If you need to be more specific, you can use a single summary route for your encryption domain values instead of a default route.

Encryption domain for policy-based tunnels

When you use policy-based tunnels, every policy entry (a CIDR block on one side of the IPSec connection) that you define generates an IPSec security association (SA) with every eligible entry on the other end of the tunnel. This pair is referred to as an encryption domain.

In this diagram, the Oracle DRG end of the IPSec tunnel has policy entries for three IPv4 CIDR blocks and one IPv6 CIDR block. The on-premises CPE end of the tunnel has policy entries two IPv4 CIDR blocks and two IPv6 CIDR blocks. Each entry generates an encryption domain with all possible entries on the other end of the tunnel. Both sides of an SA pair must use the same version of IP. The result is a total of eight encryption domains.

Diagram showing multiple encryption domains and how to determine their number.
Important

If your CPE supports only policy-based tunnels, be aware of the following restrictions.

  • Site-to-Site VPN supports multiple encryption domains, but has an upper limit of 50 encryption domains.
  • If you had a situation similar to the example above and only configured three of the six possible IPv4 encryption domains on the CPE side, the link would be listed in a "Partial UP" state since all possible encryption domains are always created on the DRG side.
  • Policy-based routing depends on Site-to-Site VPN v2. See Updated Site-to-Site VPN service for more about Site-to-Site VPN v2.
  • Depending on when your tunnel was created you might not be able to edit an existing tunnel to use policy-based routing and might need to replace the tunnel with a new IPSec tunnel.
  • The CIDR blocks used on the Oracle DRG end of the tunnel can't overlap the CIDR blocks used on the on-premises CPE end of the tunnel.
  • An encryption domain must always be between two CIDR blocks of the same IP version.

If Your CPE Is Behind a NAT Device

In general, the CPE IKE identifier configured on your end of the connection must match the CPE IKE identifier that Oracle is using. By default, Oracle uses the CPE's public IP address, which you provide when you create the CPE object in the Oracle Console. However, if your CPE is behind a NAT device, the CPE IKE identifier configured on your end might be the CPE's private IP address, as show in the following diagram.

This image shows the CPE behind a NAT device, the public and private IP addresses, and the CPE IKE identifier.
Note

Some CPE platforms do not allow you to change the local IKE identifier. If you cannot, you must change the remote IKE ID in the Oracle Console to match your CPE's local IKE ID. You can provide the value either when you set up the IPSec connection, or later, by editing the IPSec connection. Oracle expects the value to be either an IP address or a fully qualified domain name (FQDN) such as cpe.example.com. For instructions, see Changing the CPE IKE Identifier That Oracle Uses.

CPE Configuration

Important

The configuration instructions in this section are provided by Oracle Cloud Infrastructure for your CPE. If you need support or further assistance, contact your CPE vendor's support directly.

The following figure shows the basic layout of the IPSec connection.

This image summarizes the general layout of the IPSec connection and tunnels.

The configuration template provided is for a Juniper SRX router running JunOS 11.0 software (or later). The template provides information for each tunnel that you must configure. Oracle recommends setting up all configured tunnels for maximum redundancy.

The configuration template refers to these items that you must provide:

  • CPE public IP address: The internet-routable IP address that is assigned to the external interface on the CPE. You or your Oracle administrator provides this value to Oracle when creating the CPE object in the Oracle Console.
  • Inside tunnel interface (required if using BGP): The IP addresses for the CPE and Oracle ends of the inside tunnel interface. You provide these values when creating the IPSec connection in the Oracle Console.
  • BGP ASN (required if using BGP): Your BGP ASN.

In addition, you must:

  • Configure the outside tunnel interface (the CPE public IP address is bound to this interface).
  • Configure the tunnel interface IDs (referred to as st0.1 and st0.2 in the following configuration template). You need multiple tunnel unit numbers per IPSec connection.
  • Configure internal routing that routes traffic between the CPE and your local network.
  • Identify the security zone for the outside interface (the following configuration template references this zone as internet_untrust).
  • Identify the security zone for the inside interface (the following configuration template references this zone as oracle_trust).
  • Identify the security zone for the tunnel interface (the following configuration template references this zone as oracle_vpn).
Important

This following configuration template from Oracle Cloud Infrastructure is a starting point for what you need to apply to your CPE. Some of the parameters referenced in the template must be unique on the CPE, and the uniqueness can only be determined by accessing the CPE. Ensure the parameters are valid on your CPE and do not overwrite any previously configured values. In particular, ensure these values are unique:

  • Policy names or numbers
  • Interface names
  • Access list numbers (if applicable)

To find parameters that you must define before applying the configuration, search for the keyword USER_DEFINED in the template.

About Using IKEv2

Oracle supports Internet Key Exchange version 1 (IKEv1) and version 2 (IKEv2). If you configure the IPSec connection in the Console to use IKEv2, you must configure your CPE to use only IKEv2 and related IKEv2 encryption parameters that your CPE supports. For a list of parameters that Oracle supports for IKEv1 or IKEv2, see Supported IPSec Parameters.

You specify the IKE version when defining the IKE gateway. In the following configuration, there's a comment showing how to configure the IKE gateway for IKEv1 versus IKEv2.

Configuration Template

View the configuration template in full screen for easier reading. 

--------------------------------------------------------------------------------------------------------------------------------------------------------------
# Configuration Template
# The configuration consists of two IPSec tunnels. Oracle highly recommends that you configure both tunnels for maximum redundancy.
--------------------------------------------------------------------------------------------------------------------------------------------------------------
# The configuration template involves setting up the following:
# PHASE 1
# PHASE 2
# SETTING THE SECURITY ZONES FOR ORACLE
# SETTING THE SECURITY POLICIES FOR ORACLE
# SETTING THE SECURITY SETTING FOR ORACLE
# SETTING BGP/STATIC ROUTING
--------------------------------------------------------------------------------------------------------------------------------------------------------------
# The configuration template has various parameters that you must define before applying the configuration.
# Search in the template for the keyword "USER_DEFINED" to find those parameters.
--------------------------------------------------------------------------------------------------------------------------------------------------------------
# PARAMETERS REFERENCED:
# oracle_headend_1 = Oracle public IP endpoint obtained from the Oracle Console.
# oracle_headend_2 = Oracle public IP endpoint obtained from the Oracle Console.
# connection_presharedkey_1 = You provide when you set up the IPSec connection in the Oracle Console, or you can use the default Oracle-provided value.
# connection_presharedkey_2 = You provide when you set up the IPSec connection in the Oracle Console, or you can use the default Oracle-provided value.
# outside_public_interface = The public interface or outside of tunnel interface which is configured with the CPE public IP address. Example: ge-0/0/1.0
# cpe_public_ip_address = The internet-routable IP address that is assigned to the public interface on the CPE. You provide this when creating the CPE object in the Oracle Console.
# inside_tunnel_interface = The internal-facing interface for the on-premises network behind the SRX that needs to reach the Oracle VCN. Example: ge-0/0/0.0
# inside_tunnel_interface_ip_address = The IP addresses for the CPE and Oracle ends of the inside tunnel interface. You provide these when creating the IPSec connection in the Oracle Console.
# inside_tunnel_interface_ip_address_neighbor = The neighbor IP address between tbe SRX and Oracle end points of the inside tunnel interface.
# internal_network_ip_range = Internal on-premise network behind the SRX that needs to reach resources in the Oracle VCN.
# bgp_asn = Your ASN
# vcn_range = VCN IP Range
--------------------------------------------------------------------------------------------------------------------------------------------------------------
  
# IPSec Tunnel 1
   
# #1: Internet Key Exchange (IKE) Configuration (Phase 1)
# Defining the IKE Proposal for Oracle
# This IKE (Phase 1) configuration template uses AES256, SHA384, Diffie-Hellman Group 5, and 28800 second (8 hours) IKE session key lifetime.
# If different parameters are required, modify this template before applying the configuration.
   
set security ike proposal oracle-ike-proposal authentication-method pre-shared-keys
set security ike proposal oracle-ike-proposal authentication-algorithm sha-384
set security ike proposal oracle-ike-proposal encryption-algorithm aes-256-cbc
set security ike proposal oracle-ike-proposal lifetime-seconds 28800
set security ike proposal oracle-ike-proposal dh-group group5
   
# Defining the IKE Policy for Oracle
# USER_DEFINED: Replace the parameters in the section below as needed
   
set security ike policy ike_pol_oracle-vpn-<oracle_headend_1> mode main
set security ike policy ike_pol_oracle-vpn-<oracle_headend_1> proposals oracle-ike-proposal
set security ike policy ike_pol_oracle-vpn-<oracle_headend_1> pre-shared-key ascii-text <connection_presharedkey_1>
   
# Setting up Public Interface with the CPE Public IP.
# USER_DEFINED: Replace the parameters in the section below as needed
   
set interfaces <outside_public_interface> unit 0 family inet address <cpe_public_ip_address>
  
# Defining the IKE Gateway for Oracle
# USER_DEFINED: Replace the parameters in the section below as needed.
# This option enables IPsec Dead Peer Detection, which causes periodic messages to be sent to ensure a Security Association remains operational.
# If you want to use IKEv1 instead, comment out the line below that ends with "version v2-only".
  
set security ike gateway gw_oracle-<oracle_headend_1> ike-policy ike_pol_oracle-vpn-<oracle_headend_1>
set security ike gateway gw_oracle-<oracle_headend_1> external-interface <outside_public_interface>
set security ike gateway gw_oracle-<oracle_headend_1> address <oracle_headend_1>
set security ike gateway gw_oracle-<oracle_headend_1> dead-peer-detection
set security ike gateway gw_oracle-<oracle_headend_1> version v2-only
set security ike gateway gw_oracle-<oracle_headend_1> local-identity inet <cpe_public_ip_address>
   
# #2: IPSec Configuration
  
# Defining the IPSec (Phase 2) Proposal for Oracle
# The IPSec proposal defines the protocol, authentication, encryption, and lifetime parameters for the IPsec security association.
# The configuration template sets AES256 for encryption, SHA1 for authentication, enables PFS group 5, and sets the IPSec session key lifetime to 3600 seconds (1 hour).
# The IPsec policy incorporates the Diffie-Hellman group and the IPsec proposal.
# If different parameters are required, modify this template before applying the configuration.
   
set security ipsec vpn-monitor-options
set security ipsec proposal oracle-ipsec-proposal protocol esp
set security ipsec proposal oracle-ipsec-proposal authentication-algorithm hmac-sha1-96
set security ipsec proposal oracle-ipsec-proposal encryption-algorithm aes-256-cbc
set security ipsec proposal oracle-ipsec-proposal lifetime-seconds 3600
  
# Defining the IPSec (PHASE 2) policy for Oracle
set security ipsec policy ipsec_pol_oracle-vpn perfect-forward-secrecy keys group5
set security ipsec policy ipsec_pol_oracle-vpn proposals oracle-ipsec-proposal
   
# Defining Security Association for Oracle
# USER_DEFINED: Replace the parameters in the section below as needed
# The IPsec Policy and IKE gateways are associated with a tunnel interface (st0.1). If other tunnels are defined on your router, you must specify a unique interface name (for example, st0.2).
# The df-bit clear option allows the SRX to fragment the packet and send it to the end host in Oracle Cloud Infrastructure to reassemble the packet.
   
set security ipsec vpn oracle-vpn-<oracle_headend_1> bind-interface st0.1
set security ipsec vpn oracle-vpn-<oracle_headend_1> vpn-monitor
set security ipsec vpn oracle-vpn-<oracle_headend_1> ike gateway gw_oracle-<oracle_headend_1>
set security ipsec vpn oracle-vpn-<oracle_headend_1> ike ipsec-policy ipsec_pol_oracle-vpn
set security ipsec vpn oracle-vpn-<oracle_headend_1> df-bit clear
set security ipsec vpn establish-tunnels immediately
   
# #3: Tunnel Interface Configuration
   
# Defining the Tunnel Interface
# USER_DEFINED: Replace the parameters in the section below as needed
   
set interfaces st0.1 family inet address <inside_tunnel_interface_ip_address>
set interfaces st0.1 family inet mtu 1430
set interfaces <inside_tunnel_interface> unit 0 family inet address <internal_network_ip_range>
  
# Setting the Security Zones for Oracle
# USER_DEFINED: Replace the parameters in the section below as needed
# Tunnel interface st0.1, inside_tunnel_interface and outside_public_interface are each defined in its own security zones.
  
set security zones security-zone oracle_vpn interfaces st0.1
set security zones security-zone oracle_trust interfaces <inside_tunnel_interface>
set security zones security-zone internet_untrust interfaces <outside_public_interface>
   
# The security zone protecting outside interface of the router must be configured to allow IKE and ping inbound traffic.
   
set security zones security-zone internet_untrust interfaces <outside_public_interface> host-inbound-traffic system-services ike
set security zones security-zone internet_untrust interfaces <outside_public_interface> host-inbound-traffic system-services ping
   
# The security zone protecting the logical tunnel interface must be configured to allow BGP inbound traffic.
   
set security zones security-zone oracle_vpn interfaces st0.1 host-inbound-traffic protocols bgp
   
# This option causes the router to reduce the Maximum Segment Size of TCP packets to prevent packet fragmentation.
   
set security flow tcp-mss ipsec-vpn mss 1387
   
# #4: Policies
  
# Setting the Security Policies for Oracle
# Policies basically define the permitted flow of traffic between defined security zones.
# The configuration template permits any ipv4 traffic sourced and destined between security zones oracle_trust and oracle_vpn.
   
set security policies from-zone oracle_trust to-zone oracle_vpn policy vpn-out match source-address any-ipv4
set security policies from-zone oracle_trust to-zone oracle_vpn policy vpn-out match destination-address any-ipv4
set security policies from-zone oracle_trust to-zone oracle_vpn policy vpn-out match application any
set security policies from-zone oracle_trust to-zone oracle_vpn policy vpn-out match source-identity any
set security policies from-zone oracle_trust to-zone oracle_vpn policy vpn-out then permit
    
 
# #5a: Border Gateway Protocol (BGP) Configuration
   
# USER_DEFINED: Replace the parameters in the section below as needed                                                                                 
# BGP is used within the tunnel to exchange prefixes between the dynamic routing gateway and your CPE. The DRG dynamically learns the routes from your on-premises network. On the Oracle side, the DRG advertises the VCN's subnets.
# The configuration template uses a basic route policy to advertise a default route to the DRG.
# To advertise additional prefixes to the Oracle VCN, add additional prefixes to the term ORACLE-DEFAULT policy. Make sure the prefix is present in the route table of the device with a valid next-hop.                                                                                  
# You configure the local BGP Autonomous System Number (BGP ASN) when you set up the IPSec connection in the Oracle Console. If you later need to change the ASN, you must recreate the CPE object and IPSec connection in the Oracle Console.  
   
set policy-options policy-statement ORACLE-DEFAULT term default from route-filter 0.0.0.0/0 exact                                                            
set policy-options policy-statement ORACLE-DEFAULT term default then accept  
set policy-options policy-statement ORACLE-DEFAULT term reject then reject
   
set protocols bgp group ebgp type external
set protocols bgp group ebgp neighbor <inside_tunnel_interface_ip_address_neighbor> export ORACLE-DEFAULT
set protocols bgp group ebgp neighbor <inside_tunnel_interface_ip_address_neighbor> peer-as 31898
set protocols bgp group ebgp neighbor <inside_tunnel_interface_ip_address_neighbor> local-as <bgp_asn>
 
 
# #5b: Static Route Configuration
 
# USER_DEFINED: Replace the parameters in the section below as needed
# In case you plan to use static routing to get traffic through the IPSec tunnels, you can point the routes down to the tunnel interfaces. You should redistribute these routes into your on-premises network. Configuration for CPE to VCN static routes:
   
set routing-options static route <vcn_range> next-hop st0.1
  
--------------------------------------------------------------------------------------------------------------------------------------------------------------
   
# IPSec Tunnel 2
   
# #1: Internet Key Exchange (IKE) Configuration (Phase 1)
# Defining the IKE Proposal for Oracle
# This IKE (Phase 1) configuration template uses AES256, SHA384, Diffie-Hellman Group 5, and 28800 second (8 hours) IKE session key lifetime.
# If different parameters are required, modify this template before applying the configuration.
   
set security ike proposal oracle-ike-proposal authentication-method pre-shared-keys
set security ike proposal oracle-ike-proposal authentication-algorithm sha-384
set security ike proposal oracle-ike-proposal encryption-algorithm aes-256-cbc
set security ike proposal oracle-ike-proposal lifetime-seconds 28800
set security ike proposal oracle-ike-proposal dh-group group5
   
# Defining the IKE Policy for Oracle
# USER_DEFINED: Replace the parameters in the section below as needed
   
set security ike policy ike_pol_oracle-vpn-<oracle_headend_2> mode main
set security ike policy ike_pol_oracle-vpn-<oracle_headend_2> proposals oracle-ike-proposal
set security ike policy ike_pol_oracle-vpn-<oracle_headend_2> pre-shared-key ascii-text <connection_presharedkey_2>
   
# Setting up Public Interface with the CPE Public IP.
# USER_DEFINED: Replace the parameters in the section below as needed
   
set interfaces <outside_public_interface> unit 0 family inet address <cpe_public_ip_address>
  
# Defining the IKE Gateway for Oracle
# USER_DEFINED: Replace the parameters in the section below as needed.
# This option enables IPsec Dead Peer Detection, which causes periodic messages to be sent to ensure a Security Association remains operational.
# If you want to use IKEv1 instead, comment out the line below that ends with "version v2-only".
  
set security ike gateway gw_oracle-<oracle_headend_2> ike-policy ike_pol_oracle-vpn-<oracle_headend_2>
set security ike gateway gw_oracle-<oracle_headend_2> external-interface <outside_public_interface>
set security ike gateway gw_oracle-<oracle_headend_2> address <oracle_headend_2>
set security ike gateway gw_oracle-<oracle_headend_2> dead-peer-detection
set security ike gateway gw_oracle-<oracle_headend_2> version v2-only
set security ike gateway gw_oracle-<oracle_headend_2> local-identity inet <cpe_public_ip_address>
   
# #2: IPSec Configuration
  
# Defining the IPSec (Phase 2) Proposal for Oracle
# The IPSec proposal defines the protocol, authentication, encryption, and lifetime parameters for our IPsec security association.
# The configuration template sets AES256 for encryption, SHA1 for authentication, enables PFS group 5, and sets the IPSec session key lifetime to 3600 seconds (1 hour).
# The IPsec policy incorporates the Diffie-Hellman group and the IPsec proposal.
# If different parameters are required, modify this template before applying the configuration.
   
set security ipsec vpn-monitor-options
set security ipsec proposal oracle-ipsec-proposal protocol esp
set security ipsec proposal oracle-ipsec-proposal authentication-algorithm hmac-sha1-96
set security ipsec proposal oracle-ipsec-proposal encryption-algorithm aes-256-cbc
set security ipsec proposal oracle-ipsec-proposal lifetime-seconds 3600
  
# Defining the IPSec (PHASE 2) policy for Oracle
set security ipsec policy ipsec_pol_oracle-vpn perfect-forward-secrecy keys group5
set security ipsec policy ipsec_pol_oracle-vpn proposals oracle-ipsec-proposal
   
# Defining Security Association for Oracle
# USER_DEFINED: Replace the parameters in the section below as needed
# The IPsec Policy and IKE gateways are associated with a tunnel interface (st0.2). If other tunnels are defined on your router, you must specify a unique interface name.
# The df-bit clear option allows the SRX to fragment the packet and send it to the end host in Oracle Cloud Infrastructure to reassemble the packet.
   
set security ipsec vpn oracle-vpn-<oracle_headend_2> bind-interface st0.2
set security ipsec vpn oracle-vpn-<oracle_headend_2> vpn-monitor
set security ipsec vpn oracle-vpn-<oracle_headend_2> ike gateway gw_oracle-<oracle_headend_2>
set security ipsec vpn oracle-vpn-<oracle_headend_2> ike ipsec-policy ipsec_pol_oracle-vpn
set security ipsec vpn oracle-vpn-<oracle_headend_2> df-bit clear
set security ipsec vpn establish-tunnels immediately
   
# #3: Tunnel Interface Configuration
   
# Defining the Tunnel Interface
# USER_DEFINED: Replace the parameters in the section below as needed
   
set interfaces st0.2 family inet address <inside_tunnel_interface_ip_address>
set interfaces st0.2 family inet mtu 1430
set interfaces <inside_tunnel_interface> unit 0 family inet address <internal_network_ip_range>
  
# Setting the Security Zones for Oracle
# USER_DEFINED: Replace the parameters in the section below as needed
# Tunnel interface st0.2, inside_tunnel_interface and outside_public_interface are each defined in its own security zones.
  
set security zones security-zone oracle_vpn interfaces st0.2
set security zones security-zone oracle_trust interfaces <inside_tunnel_interface>
set security zones security-zone internet_untrust interfaces <outside_public_interface>
   
# The security zone protecting outside interface of the router must be configured to allow IKE and ping inbound traffic.
   
set security zones security-zone internet_untrust interfaces <outside_public_interface> host-inbound-traffic system-services ike
set security zones security-zone internet_untrust interfaces <outside_public_interface> host-inbound-traffic system-services ping
   
# The security zone protecting the logical tunnel interface must be configured to allow BGP inbound traffic.
   
set security zones security-zone oracle_vpn interfaces st0.2 host-inbound-traffic protocols bgp
   
# This option causes the router to reduce the Maximum Segment Size of TCP packets to prevent packet fragmentation.
   
set security flow tcp-mss ipsec-vpn mss 1387
   
# #4: Policies
  
# Setting the Security Policies for Oracle
# Policies basically define the permitted flow of traffic between defined security zones.
# The configuration template permits any IPv4 traffic sourced and destined between security zones oracle_trust and oracle_vpn.
   
set security policies from-zone oracle_trust to-zone oracle_vpn policy vpn-out match source-address any-ipv4
set security policies from-zone oracle_trust to-zone oracle_vpn policy vpn-out match destination-address any-ipv4
set security policies from-zone oracle_trust to-zone oracle_vpn policy vpn-out match application any
set security policies from-zone oracle_trust to-zone oracle_vpn policy vpn-out match source-identity any
set security policies from-zone oracle_trust to-zone oracle_vpn policy vpn-out then permit
   
# #5a: Border Gateway Protocol (BGP) Configuration
   
# USER_DEFINED: Replace the parameters in the section below as needed                                                                                 
# BGP is used within the tunnel to exchange prefixes between the dynamic routing gateway and your CPE. The DRG dynamically learns the routes from your on-premises network. On the Oracle side, the DRG advertises the VCN's subnets.
# THe configuration template uses a basic route policy to advertise a default route to the DRG.
# To advertise additional prefixes to the Oracle VCN, add additional prefixes to the term ORACLE-DEFAULT policy. Make sure the prefix is present in the route table of the device with a valid next-hop.                                                                                  
# You configure the local BGP Autonomous System Number (BGP ASN) when you set up the IPSec connection in the Oracle Console. If you later need to change the ASN, you must recreate the CPE object and IPSec connection in the Oracle Console.  
   
set policy-options policy-statement ORACLE-DEFAULT term default from route-filter 0.0.0.0/0 exact                                                            
set policy-options policy-statement ORACLE-DEFAULT term default then accept  
set policy-options policy-statement ORACLE-DEFAULT term reject then reject
   
set protocols bgp group ebgp type external
set protocols bgp group ebgp neighbor <inside_tunnel_interface_ip_address_neighbor> export ORACLE-DEFAULT
set protocols bgp group ebgp neighbor <inside_tunnel_interface_ip_address_neighbor> peer-as 31898
set protocols bgp group ebgp neighbor <inside_tunnel_interface_ip_address_neighbor> local-as <bgp_asn>
  
# #5b: Static Route Configuration
 
# USER_DEFINED: Replace the parameters in the section below as needed
# In case you plan to use static routing to get traffic through the IPSec tunnels, you can point the routes down to the tunnel interfaces. You should redistribute these routes into your on-premises network. Configuration for CPE to VCN static routes:
  
set routing-options static route <vcn_range> next-hop st0.2

Verification

Use the following command to verify security associations (SAs).


show security ipsec security-associations

Use the following command to check the BGP status.


show bgp summary

Use the following commands to check the routes advertised to and received from Oracle Cloud Infrastructure.


show route advertising-protocol bgp <neighbor-address>
  
show route receive-protocol bgp <neighbor-address>

A Monitoring service is also available from Oracle Cloud Infrastructure to actively and passively monitor your cloud resources. For information about monitoring your Site-to-Site VPN, see Site-to-Site VPN Metrics.

If you have issues, see Site-to-Site VPN Troubleshooting.