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VLAN-Based Security for Modern Service-Provision Networks

VLAN-Based Security for Modern Service-Provision Networks. Version 0.9 October, 2000 Bill Woodcock Packet Clearing House. We Have Linguistic Problems, not Technological Problems. The technology is much, much more flexible than most people’s ability to comprehend the problem-space.

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VLAN-Based Security for Modern Service-Provision Networks

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  1. VLAN-Based Security for Modern Service-Provision Networks Version 0.9 October, 2000 Bill Woodcock Packet Clearing House

  2. We Have Linguistic Problems, not Technological Problems • The technology is much, much more flexible than most people’s ability to comprehend the problem-space. • The problem is in finding a mental model which allows users to comprehend the problems and their solutions, not in finding a technology to solve the problem.

  3. Legacy Firewall Terminology • Historical distinction between “packet filtering firewalls” and “stateful-inspection firewalls” no longer very useful in the real world. • “inside,” “outside” and “DMZ” nomenclature limits lay-people’s ability to understand security.

  4. Old Enterprise Solution: • Stateful-inspection box • Usually an application on top of Windows. • Immense differential between the complexity of the system and what’s exposed to the operator. • Usually very slow. • Usually very low MTBF. • Three 10/100 Ethernet interfaces. • No protection against stepping-stone attacks. • No protection against untrusted users.

  5. Stepping-Stone Attack Attacker “Outside” “Inside” Allowed Port Normal Server Vulnerable Server

  6. Stepping-Stone Attack Attacker “Outside” Attack Channel “Inside” Allowed Port Normal Server Vulnerable Server

  7. Stepping-Stone Attack Attacker “Outside” Control Channel “Inside” Allowed Port Normal Server Now At Risk Compromised Server

  8. Stepping-Stone Attack Attacker “Outside” “Inside” Stepping-Stone Attack Normal Server Now At Risk Compromised Server

  9. Stepping-Stone Attack Attacker “Outside” Control Channel “Inside” Normal Server Compromised Compromised Server

  10. Untrusted User Attack “Outside” Allowed Ports Intranet Server Many Allowed Ports “DMZ” “Inside” Normal User Untrusted User

  11. Untrusted User Attack “Outside” Allowed Ports Intranet Server Many Allowed Ports “DMZ” “Inside” Attack Channel Normal User Untrusted User

  12. Untrusted User Attack “Outside” Allowed Ports Compromised Server Many Allowed Ports “DMZ” “Inside” Control Channel Normal User Untrusted User

  13. Modern Firewalling • Don’t add points of failure. Make full use of the high-MTBF equipment you already have. • Don’t slow things down. • Don’t invite Bill Gates into your network. • Security needs should define your security policy, not some coincidental number of physical interfaces on a box.

  14. Simple Packet Filter “Outside” One Large Packet Filter Router “Inside” Switch Fabric

  15. Simple Packet Filter “Outside” One Large Packet Filter Router “Inside” Switch Fabric

  16. VLAN-Based Firewalling “Outside” Many Small Packet Filters Router 802.1Q VLAN Trunk Switch Fabric Many “Insides”

  17. VLAN-Based Firewalling “Outside” Many Small Packet Filters Router 802.1Q Switch Fabric “Insides”

  18. Relative Processing Speed One large packet filter (40 lines) Average exit after 20 lines

  19. Relative Processing Speed Routing process selects output ruleset Ten small packet filters (4 lines each) Average exit after 2 lines Routing is cheap, ruleset processing is expensive. Use the router for what it’s good at.

  20. What This Looks Like: Switch hostname OAK-Switch-3 ! interface FastEthernet0/41 description VLAN_341-OAK_DNS-131.161.2.0/30 switchport access vlan 341 speed 100 full-duplex OAK-Switch-3# vlan database OAK-Switch-3(vlan)# vlan 341 name VLAN_341-OAK_DNS-131.161.2.0/30 OAK-Switch-3(vlan)# exit APPLY completed. Exiting....

  21. What This Looks Like: Router hostname OAK-Firewall ! interface FastEthernet0/0 description 802.1Q VLAN Trunk to OAK-Switch-1 no ip address speed 100 full-duplex ! interface FastEthernet0/0.341 description VLAN_341-OAK_DNS-131.161.2.0/30 encapsulation dot1Q 341 ip address 131.161.2.2 255.255.255.252 ip access-group ACL-341-OAK_DNS-IN in ip access-group ACL-341-OAK_DNS-OUT out ! ip access-list extended ACL-341-OAK_DNS-IN permit udp host 131.161.2.1 eq domain any permit udp host 131.161.2.1 any eq domain permit tcp host 131.161.2.1 any eq domain permit tcp host 131.161.2.1 eq domain any deny icmp any any port-unreachable deny udp any any gt 0 log-input deny tcp any any gt 0 log-input deny ip any any log-input ip access-list extended ACL-341-OAK_DNS-OUT permit udp any host 131.161.2.1 eq domain permit udp any eq domain host 131.161.2.1 gt 1023 permit tcp any any established permit tcp any host 131.161.2.1 eq domain deny udp any any eq netbios-ns deny icmp any any deny udp any any gt 0 log deny tcp any any gt 0 log deny ip any any log

  22. Example With VPN Endpoint “Outside” Router Rulesets 802.1Q Trunk Switch Access Ports VPN Endpoint Server

  23. Example With VPN Endpoint Traffic enters network from the commodity network Rulesets

  24. Example With VPN Endpoint Rulesets First ruleset guarantees that only IPSec traffic will reach the VPN endpoint VPN endpoint is protected against non-IPSec attack

  25. Example With VPN Endpoint Rulesets IPSec traffic enters “outside” of VPN endpoint

  26. Example With VPN Endpoint Rulesets Decrypted IP traffic leaves “inside” of VPN endpoint

  27. Example With VPN Endpoint Rulesets Second ruleset defines which internal resources VPN users are allowed access to Users who have undergone visual authentication are differentiated from those who may have left a home terminal logged in

  28. Example With VPN Endpoint Third ruleset defines which services are accessible on each particular server

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