1. ASA Multiple Context Done By: Tariq Bader – CCIE # 35627 1

2. INTRODUCTION 2

3. Introduction ASA firewall supports software virtualization, by means of so-called firewall contexts. Every context has its own set of routing, filtering/inspection and address translation rules. All contexts must be in either routing or transparent firewall mode – you cannot mix modes in different contexts. 3

4. Introduction Supported Features: – Only static routing – Firewall features – IPS – Management Unsupported Features (for ASA pre 9 versions) – VPN termination – Dynamic Routing Protocol – QoS New features introduced in ASA 9: – Site-to-Site VPN in multiple context mode – New resource type for site-to-site VPN tunnels – Dynamic routing in Security Contexts – New resource type for routing table entries – Mixed firewall mode support in multiple context mode 4

5. Introduction Where do we use Multiple context? – In ISPs, were they sell security services to many customers, they implement a cost-effective, space saving solution. – Large Enterprises who keeps their departments completely separated. – Basically, we use multiple context whenever there is a network that requires more than one security appliance. Note: The multiple context feature is not supported on the ASA 5505 Series Adaptive Security Appliance. 5

6. CONTEXT TYPES 6

7. Context Types System Context Admin Context Normal Context 7

8. System Context The System administrator adds and manages contexts by the configuration of each context configuration location, allocated interfaces, and other context operational parameters in the system configuration. The system configuration identifies basic settings for the security appliance. You cannot assign any IP addresses when you are under the system context, with exception to the management interface. You can upgrade or downgrade the PIX/ASA software only in the System EXEC mode, not in the other context modes. 8

9. Admin Context The admin context is like any other context, except that when a user logs in to the admin context, that user will have system administrator rights, and can access the system and all other contexts Admin context configuration must reside on the Flash memory. If you convert from a Single mode to the Multiple Context mode, the admin context is created automatically and the configuration file will be created on the flash memory This context could be combined with any regular user context or be dedicated. Note: Admin context (when it is dedicated) is not counted in the context license. For example, if you get the license for two contexts, you are allowed to have the admin context and two other contexts. 9

10. Normal Context Is the actual partitioned firewall. Contexts can be accessed via Console, Telnet, SSH, and ASDM If you log in to an non-admin context, you can only access the configuration for that context 10

11. CONFIGURATION 11

12. Configuration Note: The ports on the switch that are connected to ASA must be in trunk mode since multiple VLAN traffic has to travel through it once the ASA interfaces are broken into sub−interfaces. 12

13. Configuration In order to turn the firewall to the multiple contexts mode, you should enter the command mode multiple when logged via the console port. Note: You may do this remotely but you risk losing connection to the box. This will force mode change to multiple and reload the appliance. If you connect to the appliance the console port, you are logging into the system context after the reload. 13

14. Configuration When you convert from single mode to multiple mode, the security appliance converts the running configuration into two files: 1.New startup configuration that comprises the system configuration. 2.admin.cfg that comprises the admin context (in the root directory of the internal Flash memory). The original running configuration is saved as old_running.cfg (in the root directory of the internal Flash memory). The original startup configuration is not saved. The security appliance automatically adds an entry for the admin context to the system configuration with the name "admin.“ 14

15. Configuration Steps You should to do the following things while logged into the system context: 1)Configure physical interfaces. You need to un- shutdown the interfaces that you want to allocate to the contexts. If you are creating sub- interfaces using VLANs, you should do it under the system context as well. 15

16. Configuration Steps 2)Define the admin context. This is a special context that allows logging in the firewall remotely (via ssh, telnet or https). This context should be configured first as the firewall won’t let you create any other contexts prior to designating the admin context using the global command admin-context. As we have said this context is automatically created When you convert from the single- context mode. 16

17. Configuration Steps 3)Define additional contexts if needed and allocate physical interfaces to the contexts. Use the command allocate-interface [ ] under the context configuration mode for interface allocation. Here is the physical interface or sub-interface name and is the name that the context sees for this interface. Using this command you can hide the real interface names from the context administrators (e.g. hide VLAN numbers), in order to provide additional level of isolation from the physical configuration. 17

18. Configuration Steps 4)Change to the context configuration, and proceed as usual. Assign interface names, security levels and IP addresses. Set up static routes for subnets not directly connected to the context – even for the subnets connected to another contexts. 18

19. Configuration Notes Every configured context should have a configuration URL defined using the command config-url to store its configuration. Without this command, the context configuration is incomplete. After the context has been defined, you may switch to the “in-context” configuration using the command changeto context. In order to access the system context remotely, you should log into the admin context using any configured remote access method and issue the command changeto system. Enter the allocate−interface command(s) before you enter the config−url command. The security appliance must assign interfaces to the context before it loads the context configuration; the context configuration can include commands that refer to interfaces (interface, nat, global...). If you enter the config−url command first, the security appliance loads the context configuration immediately. If the context contains any commands that refer to interfaces, those commands fail. Use the command write memory all in the system context to save all contexts configuration on the persistent storage. You may also save configuration for a context individually when logged under the particular context using the command write memory. 19

20. Configuration Notes Physical interfaces could be shared among contexts, i.e. you may assign the same interface to different contexts. Interface sharing is the unique feature of the ASA firewall contexts, and this is what makes it stand apart from IOS VRF technology.erface to different contexts. When an interface is shared between two contexts, certain classification rules should be applied to determine which context the incoming packets should use. 20

21. Configuration Notes If there is a shared physical interface between the contexts, each context could generally have different IP and MAC addresses on this interface. It is possible to share the IP address as well, though. If you want to assign the same IP address to the shared interfaces in multiple context mode you’ll need to give the logical interfaces a separate MAC address. You may use non-overlapping subnets or simply different IPs on the same subnet. By default both contexts will inherit the same MAC address from the shared physical interface. This might result in the firewall not being able to classify the incoming traffic properly. Use the command mac-address auto in the system context to automatically generate a MAC address for every new “virtual” interface. 21

22. Configuration 22 In order to enable multiple mode, enter this command: hostname(config)# mode multiple You are prompted to reboot the security appliance. CiscoASA(config)# mode multiple WARNING: This command will change the behavior of the device WARNING: This command will initiate a Reboot Proceed with change mode? [confirm] Convert the system configuration? [confirm] ! The old running configuration file will be written to flash The admin context configuration will be written to flash The new running configuration file was written to flash Security context mode: multiple *** *** −−− SHUTDOWN NOW −−− *** *** Message to all terminals: *** *** change mode Rebooting....

23. Configuration Creating a new context: Ciscoasa(config)# Context ContextA Ciscoasa(config-ctx)# description text Ciscoasa(config-ctx)# Allocate-interface [mapped name] Ciscoasa(config-ctx)# Config-url url You can’t rename the context, you will have to delete it, then create a new one with the new name. – Delete a Context: No context ContextA 23

24. Example Scenario 24

25. FIREWALL CONTEXTS ROUTING 25

26. Firewall Context Routing As mentioned previously, in the multiple- context mode the firewall supports only static routing. you need to configure a static route for every non-directly connected subnet for a firewall context or set up a static default route. All adjacent routers should be also configured with static routes to allow for full connectivity. 26

27. Firewall Context Routing Routing between contexts: – firewall contexts do not share IP routing tables, and thus if you want to establish communications between the routing contexts you need either of the following: 1.Configure each context with a set of static routes for the subnets connected or located behind the other context. 2.Use an external router that has full knowledge of the subnets behind each of the contexts to provide connectivity. 27

28. Firewall Context Routing Context Cascading – Recall that physical interfaces could be shared between the contexts. – In some scenarios, you may even configure the same physical interface as the inside for one context and outside for another. This is called context cascading. *Look at the figure below: 28

29. FIREWALL CONTEXTS CLASSIFICATION 29

30. Firewall Contexts Classification It is easy to assign an input packet to the context if the interface where it has been received is uniquely allocated to the context. If the interface is shared, additional rules are needed. 30

31. Firewall Contexts Classification Shared interfaces classification rules: 1)The firewall looks at the destination MAC address of the packet – the destination MAC designated the “next-hop” for the packet.* 2)If the MAC address is the same in both contexts for the same interface, the firewall attempts to use NAT configuration in every context to resolve the “conflicts”. This may happen if you intentionally assign the same IP address to both contexts or did not assign different MAC addresses to the shared interfaces. The firewall attempts to match the destination IP address and TCP/UDP port information in the packet with the active translation slots in every context. The context with the matching translation slot is selected as the target context. This type of classification allows sharing the same IP subnet or even IP address on the shared interface. You are not required to have unique MAC addresses in each context, as the translation slots are used for traffic classification. 31

32. Firewall Contexts Classification Shared interfaces classification rules: 3)If all contexts on the shared interface use the same IP address/MAC then you cannot access the contexts on the shared interface. Why? Because for traffic destined to the firewall itself, it classifies based on the destination IP address. So it is generally recommended to use separate IP addresses (MAC could be the same) on the shared interfaces. 32

33. RESOURCE MANAGEMENT 33

34. Resource Management The firewall has limited resources, shared between the contexts. The resources include concurrent connections, inspections, translation slots, management sessions (telnet, ssh and https) number of inside hosts and so on. Some of those resources are limited based on the licensing option – e.g. the number of inside hosts. Others are limited by the firewall hardware. 34

35. Resource Management In order to avoid resource contention and exhaustion, the firewall allows limiting per-context resources using the resource class concept. Every class specifies the amount of resource available to a context. Classes are assigned to the contexts to enforce the limits. By default, all contexts are assigned class “default”. Note that contexts do not “share” the particular class resources. They only inherit the resource limits set by a class. 35

36. Resource Management When you create a new class, it inherits all limits from the “default” resource class. When you re-define any particular limit in the new class, you automatically override the default setting for this limit. You may also configure the default class settings and all classes will inherit these values, unless they redefine them. 36

37. Resource Management 37

38. Resource Management The appliance never “reserves” any resources for classes. It simply uses them to compute the resource limits and satisfies any request that is within the limit for a given class. For example, suppose the system supports up to 1000 connection maximum, and you create new class with the limit of 500 connections. You assign this class to 3 contexts. At the peak of their usage every context may request up to 500 connections, exceeding the total limit of 1000. Thus it is up to the administrator to properly set limits and prevent resource starvation. You may set resource limits in absolute values (e.g. number of connections or hosts) or in percent's of the maximum resource available. 38

39. Resource Management The syntax is: class limit-resource [ |{1-100%}] – Some resources, like Conns, Inspects and Syslogs support rate limiting, using the command: limit-resource rate [{Conns|Inspects|Syslogs}|{1-100%}] 39

40. Q&A 40