• Monitoring the Transparent Firewall
  • Firewall Mode Examples
  • Feature History for the Firewall Mode
  • Configuring the Transparent or Routed Firewall

    This chapter describes how to set the firewall mode to routed or transparent, as well as how the firewall works in each firewall mode. This chapter also includes information about customizing the transparent firewall operation.

    You must set the same firewall mode for all contexts, not individually for each context in multiple context mode.

    Information About the Firewall Mode

    Information About Routed Firewall Mode

    In routed mode, the ASA is considered to be a router hop in the network. Routed mode supports many interfaces. Each interface is on a different subnet. You can share interfaces between contexts.

    The ASA acts as a router between connected networks, and each interface requires an IP address on a different subnet. The ASA supports multiple dynamic routing protocols. However, we recommend using the advanced routing capabilities of the upstream and downstream routers instead of relying on the ASA for extensive routing needs.

    Information About Transparent Firewall Mode

    Traditionally, a firewall is a routed hop and acts as a default gateway for hosts that connect to one of its screened subnets. A transparent firewall, on the other hand, is a Layer 2 firewall that acts like a “bump in the wire,” or a “stealth firewall,” and is not seen as a router hop to connected devices.

    Using the Transparent Firewall in Your Network

    The ASA connects the same network between its interfaces. Because the firewall is not a routed hop, you can easily introduce a transparent firewall into an existing network.

    Figure 5-1 shows a typical transparent firewall network where the outside devices are on the same subnet as the inside devices. The inside router and hosts appear to be directly connected to the outside router.

    Figure 5-1 Transparent Firewall Network

     

    92411.jpg

    Bridge Groups

    If you do not want the overhead of security contexts, or want to maximize your use of security contexts, you can group interfaces together in a bridge group, and then configure multiple bridge groups, one for each network. Bridge group traffic is isolated from other bridge groups; traffic is not routed to another bridge group within the ASA, and traffic must exit the ASA before it is routed by an external router back to another bridge group in the ASA. Although the bridging functions are separate for each bridge group, many other functions are shared between all bridge groups. For example, all bridge groups share a syslog server or AAA server configuration. For complete security policy separation, use security contexts with one bridge group in each context.

    Figure 5-2 shows two networks connected to the ASA, which has two bridge groups.

    Figure 5-2 Transparent Firewall Network with Two Bridge Groups

     

    254279.jpg
    note.gif

    Noteblank.gif Each bridge group requires a management IP address. The ASA uses this IP address as the source address for packets originating from the bridge group. The management IP address must be on the same subnet as the connected network. For another method of management, see the “Management Interface (ASA 5510 and Higher)” section.

    The ASA does not support traffic on secondary networks; only traffic on the same network as the management IP address is supported.


    Management Interface (ASA 5510 and Higher)

    In addition to each bridge group management IP address, you can add a separate Management slot / port interface that is not part of any bridge group, and that allows only management traffic to the ASA. For more information, see the “Management Interface” section.

    Allowing Layer 3 Traffic

    • Unicast IPv4 and IPv6 traffic is allowed through the transparent firewall automatically from a higher security interface to a lower security interface, without an ACL.
    note.gif

    Noteblank.gif Broadcast and multicast traffic can be passed using access rules. See the “Allowing Broadcast and Multicast Traffic through the Transparent Firewall Using Access Rules” section for more information.


    • ARPs are allowed through the transparent firewall in both directions without an access list. ARP traffic can be controlled by ARP inspection.
    • For Layer 3 traffic travelling from a low to a high security interface, an extended access list is required on the low security interface. See “Adding an Extended Access Control List,” for more information.

    Allowed MAC Addresses

    The following destination MAC addresses are allowed through the transparent firewall. Any MAC address not on this list is dropped.

    • TRUE broadcast destination MAC address equal to FFFF.FFFF.FFFF
    • IPv4 multicast MAC addresses from 0100.5E00.0000 to 0100.5EFE.FFFF
    • IPv6 multicast MAC addresses from 3333.0000.0000 to 3333.FFFF.FFFF
    • BPDU multicast address equal to 0100.0CCC.CCCD
    • AppleTalk multicast MAC addresses from 0900.0700.0000 to 0900.07FF.FFFF

    Passing Traffic Not Allowed in Routed Mode

    In routed mode, some types of traffic cannot pass through the ASA even if you allow it in an access list. The transparent firewall, however, can allow almost any traffic through using either an extended access list (for IP traffic) or an EtherType access list (for non-IP traffic).

    Non-IP traffic (for example AppleTalk, IPX, BPDUs, and MPLS) can be configured to go through using an EtherType access list.

    note.gif

    Noteblank.gif The transparent mode ASA does not pass CDP packets packets, or any packets that do not have a valid EtherType greater than or equal to 0x600. An exception is made for BPDUs, which are supported.


    Passing Traffic For Routed-Mode Features

    For features that are not directly supported on the transparent firewall, you can allow traffic to pass through so that upstream and downstream routers can support the functionality. For example, by using an extended access list, you can allow DHCP traffic (instead of the unsupported DHCP relay feature) or multicast traffic such as that created by IP/TV. You can also establish routing protocol adjacencies through a transparent firewall; you can allow OSPF, RIP, EIGRP, or BGP traffic through based on an extended access list. Likewise, protocols like HSRP or VRRP can pass through the ASA.

    BPDU Handling

    To prevent loops using the Spanning Tree Protocol, BPDUs are passed by default. To block BPDUs, you need to configure an EtherType access list to deny them. If you are using failover, you might want to block BPDUs to prevent the switch port from going into a blocking state when the topology changes. See the “Transparent Firewall Mode Requirements” section for more information.

    MAC Address vs. Route Lookups

    When the ASA runs in transparent mode, the outgoing interface of a packet is determined by performing a MAC address lookup instead of a route lookup.

    Route lookups, however, are necessary for the following traffic types:

    • Traffic originating on the ASA—For example, if your syslog server is located on a remote network, you must use a static route so the ASA can reach that subnet.
    • Traffic that is at least one hop away from the ASA with NAT enabled—The ASA needs to perform a route lookup to find the next hop gateway; you need to add a static route on the ASA for the real host address.
    • Voice over IP (VoIP) and DNS traffic with inspection enabled, and the endpoint is at least one hop away from the ASA—For example, if you use the transparent firewall between a CCM and an H.323 gateway, and there is a router between the transparent firewall and the H.323 gateway, then you need to add a static route on the ASA for the H.323 gateway for successful call completion. If you enable NAT for the inspected traffic, a static route is required to determine the egress interface for the real host address that is embedded in the packet. Affected applications include:

    blank.gif CTIQBE

    blank.gif DNS

    blank.gif GTP

    blank.gif H.323

    blank.gif MGCP

    blank.gif RTSP

    blank.gif SIP

    blank.gif Skinny (SCCP)

    ARP Inspection

    By default, all ARP packets are allowed through the ASA. You can control the flow of ARP packets by enabling ARP inspection.

    When you enable ARP inspection, the ASA compares the MAC address, IP address, and source interface in all ARP packets to static entries in the ARP table, and takes the following actions:

    • If the IP address, MAC address, and source interface match an ARP entry, the packet is passed through.
    • If there is a mismatch between the MAC address, the IP address, or the interface, then the ASA drops the packet.
    • If the ARP packet does not match any entries in the static ARP table, then you can set the ASA to either forward the packet out all interfaces (flood), or to drop the packet.
    note.gif

    Noteblank.gif The dedicated management interface, if present, never floods packets even if this parameter is set to flood.


    ARP inspection prevents malicious users from impersonating other hosts or routers (known as ARP spoofing). ARP spoofing can enable a “man-in-the-middle” attack. For example, a host sends an ARP request to the gateway router; the gateway router responds with the gateway router MAC address. The attacker, however, sends another ARP response to the host with the attacker MAC address instead of the router MAC address. The attacker can now intercept all the host traffic before forwarding it on to the router.

    ARP inspection ensures that an attacker cannot send an ARP response with the attacker MAC address, so long as the correct MAC address and the associated IP address are in the static ARP table.

    MAC Address Table

    The ASA learns and builds a MAC address table in a similar way as a normal bridge or switch: when a device sends a packet through the ASA, the ASA adds the MAC address to its table. The table associates the MAC address with the source interface so that the ASA knows to send any packets addressed to the device out the correct interface.

    The ASA 5505 includes a built-in switch; the switch MAC address table maintains the MAC address-to-switch port mapping for traffic within each VLAN. This section only discusses the bridge MAC address table, which maintains the MAC address-to-VLAN interface mapping for traffic that passes between VLANs.

    Because the ASA is a firewall, if the destination MAC address of a packet is not in the table, the ASA does not flood the original packet on all interfaces as a normal bridge does. Instead, it generates the following packets for directly connected devices or for remote devices:

    • Packets for directly connected devices—The ASA generates an ARP request for the destination IP address, so that the ASA can learn which interface receives the ARP response.
    • Packets for remote devices—The ASA generates a ping to the destination IP address so that the ASA can learn which interface receives the ping reply.

    The original packet is dropped.

    Licensing Requirements for the Firewall Mode

     

    Model
    License Requirement

    All models

    Base License.

    Default Settings

    The default mode is routed mode.

    Transparent Mode Defaults

    • By default, all ARP packets are allowed through the ASA.
    • If you enable ARP inspection, the default setting is to flood non-matching packets.
    • The default timeout value for dynamic MAC address table entries is 5 minutes.
    • By default, each interface automatically learns the MAC addresses of entering traffic, and the ASA adds corresponding entries to the MAC address table.

    Guidelines and Limitations

    Context Mode Guidelines

    Set the same firewall mode for all contexts.

    Transparent Firewall Guidelines

    • In transparent firewall mode, the management interface updates the MAC address table in the same manner as a data interface; therefore you should not connect both a management and a data interface to the same switch unless you configure one of the switch ports as a routed port (by default Cisco Catalyst switches share a MAC address for all VLAN switch ports). Otherwise, if traffic arrives on the management interface from the physically-connected switch, then the ASA updates the MAC address table to use the management interface to access the switch, instead of the data interface. This action causes a temporary traffic interruption; the ASA will not re-update the MAC address table for packets from the switch to the data interface for at least 30 seconds for security reasons.
    • Each directly-connected network must be on the same subnet.
    • Do not specify the bridge group management IP address as the default gateway for connected devices; devices need to specify the router on the other side of the ASA as the default gateway.
    • The default route for the transparent firewall, which is required to provide a return path for management traffic, is only applied to management traffic from one bridge group network. This is because the default route specifies an interface in the bridge group as well as the router IP address on the bridge group network, and you can only define one default route. If you have management traffic from more than one bridge group network, you need to specify a static route that identifies the network from which you expect management traffic.

    See the “Guidelines and Limitations” section for more guidelines.

    IPv6 Guidelines

    Supports IPv6.

    Additional Guidelines and Limitations

    • When you change firewall modes, the ASA clears the running configuration because many commands are not supported for both modes. The startup configuration remains unchanged. If you reload without saving, then the startup configuration is loaded, and the mode reverts back to the original setting. See the “Setting the Firewall Mode” section for information about backing up your configuration file.
    • If you download a text configuration to the ASA that changes the mode with the firewall transparent command, be sure to put the command at the top of the configuration; the ASA changes the mode as soon as it reads the command and then continues reading the configuration you downloaded. If the command appears later in the configuration, the ASA clears all the preceding lines in the configuration. See the “Downloading Software or Configuration Files to Flash Memory” section for information about downloading text files.

    Unsupported Features in Transparent Mode

    Table 5-1 lists the features are not supported in transparent mode.

     

    Table 5-1 Unsupported Features in Transparent Mode

    Feature
    Description

    Dynamic DNS

    DHCP relay

    The transparent firewall can act as a DHCP server, but it does not support the DHCP relay commands. DHCP relay is not required because you can allow DHCP traffic to pass through using two extended access lists: one that allows DCHP requests from the inside interface to the outside, and one that allows the replies from the server in the other direction.

    Dynamic routing protocols

    You can, however, add static routes for traffic originating on the ASA. You can also allow dynamic routing protocols through the ASA using an extended access list.

    Multicast IP routing

    You can allow multicast traffic through the ASA by allowing it in an extended access list.

    QoS

    VPN termination for through traffic

    The transparent firewall supports site-to-site VPN tunnels for management connections only. It does not terminate VPN connections for traffic through the ASA. You can pass VPN traffic through the ASA using an extended access list, but it does not terminate non-management connections. Clientless SSL VPN is also not supported.

    Unified Communications

    Setting the Firewall Mode

    This section describes how to change the firewall mode.

    note.gif

    Noteblank.gif We recommend that you set the firewall mode before you perform any other configuration because changing the firewall mode clears the running configuration.


    Prerequisites

    When you change modes, the ASA clears the running configuration (see the “Guidelines and Limitations” section for more information).

    • If you already have a populated configuration, be sure to back up your configuration before changing the mode; you can use this backup for reference when creating your new configuration. See the “Backing Up Configuration Files or Other Files” section.
    • Use the CLI at the console port to change the mode. If you use any other type of session, including the ASDM Command Line Interface tool or SSH, you will be disconnected when the configuration is cleared, and you will have to reconnect to the ASA using the console port in any case.
    • Set the mode in the system execution space.

    Detailed Steps

     

    Command
    Purpose

    firewall transparent

     

     

    hostname(config)# firewall transparent

    Sets the firewall mode to transparent. To change the mode to routed, enter the no firewall transparent command.

    Note You are not prompted to confirm the firewall mode change; the change occurs immediately.

    Configuring ARP Inspection for the Transparent Firewall

    This section describes how to configure ARP inspection and includes the following topics:

    Task Flow for Configuring ARP Inspection

    To configure ARP Inspection, perform the following steps:


    Step 1blank.gif Add static ARP entries according to the “Adding a Static ARP Entry” section. ARP inspection compares ARP packets with static ARP entries in the ARP table, so static ARP entries are required for this feature.

    Step 2blank.gif Enable ARP inspection according to the “Enabling ARP Inspection” section.


     

    Adding a Static ARP Entry

    ARP inspection compares ARP packets with static ARP entries in the ARP table. Although hosts identify a packet destination by an IP address, the actual delivery of the packet on Ethernet relies on the Ethernet MAC address. When a router or host wants to deliver a packet on a directly connected network, it sends an ARP request asking for the MAC address associated with the IP address, and then delivers the packet to the MAC address according to the ARP response. The host or router keeps an ARP table so it does not have to send ARP requests for every packet it needs to deliver. The ARP table is dynamically updated whenever ARP responses are sent on the network, and if an entry is not used for a period of time, it times out. If an entry is incorrect (for example, the MAC address changes for a given IP address), the entry times out before it can be updated.

    note.gif

    Noteblank.gif The transparent firewall uses dynamic ARP entries in the ARP table for traffic to and from the ASA, such as management traffic.


    Detailed Steps

     

    Command
    Purpose

    arp interface_name ip_address mac_address

     

     

    hostname(config)# arp outside 10.1.1.1 0009.7cbe.2100

    Adds a static ARP entry.

    Examples

    For example, to allow ARP responses from the router at 10.1.1.1 with the MAC address 0009.7cbe.2100 on the outside interface, enter the following command:

    hostname(config)# arp outside 10.1.1.1 0009.7cbe.2100
     

    What to Do Next

    Enable ARP inspection according to the “Enabling ARP Inspection” section.

    Enabling ARP Inspection

    This section describes how to enable ARP inspection.

    Detailed Steps

     

    Command
    Purpose

    arp-inspection interface_name enable [ flood | no-flood ]

     

     

    hostname(config)# arp-inspection outside enable no-flood

    Enables ARP inspection.

    The flood keyword forwards non-matching ARP packets out all interfaces, and no-flood drops non-matching packets.

    Note The default setting is to flood non-matching packets. To restrict ARP through the ASA to only static entries, then set this command to no-flood.

    Examples

    For example, to enable ARP inspection on the outside interface, and to drop all non-matching ARP packets, enter the following command:

    hostname(config)# arp-inspection outside enable no-flood
     

    Customizing the MAC Address Table for the Transparent Firewall

    This section describes how you can customize the MAC address table and includes the following sections:

    Adding a Static MAC Address

    Normally, MAC addresses are added to the MAC address table dynamically as traffic from a particular MAC address enters an interface. You can add static MAC addresses to the MAC address table if desired. One benefit to adding static entries is to guard against MAC spoofing. If a client with the same MAC address as a static entry attempts to send traffic to an interface that does not match the static entry, then the ASA drops the traffic and generates a system message. When you add a static ARP entry (see the “Adding a Static ARP Entry” section), a static MAC address entry is automatically added to the MAC address table.

    Detailed Steps

     

    Command
    Purpose

    Step 1

    mac-address-table static interface_name mac_address

     

     

    hostname(config)# mac-address-table static inside 0009.7cbe.2100

    Adds a static MAC address entry.

    The interface_name is the source interface.

    Step 2

    (Optional)

    mac-address-table aging-time timeout_value

     

     

    hostname(config)# mac-address-table aging-time 10

    Sets the MAC address entry timeout.

    The timeout_value (in minutes) is between 5 and 720 (12 hours). 5 minutes is the default.

    Disabling MAC Address Learning

    By default, each interface automatically learns the MAC addresses of entering traffic, and the ASA adds corresponding entries to the MAC address table. You can disable MAC address learning if desired, however, unless you statically add MAC addresses to the table, no traffic can pass through the ASA.

    To disable MAC address learning, enter the following command:

     

    Command
    Purpose

    mac-learn interface_name disable

     

     

    hostname(config)# mac-learn inside disable

    Disables MAC address learning.

    The no form of this command reenables MAC address learning. The clear configure mac-learn command reenables MAC address learning on all interfaces.

    Monitoring the Transparent Firewall

    Monitoring ARP Inspection

    To monitor ARP inspection, perform the following task:

     

    Command
    Purpose
    show arp-inspection

    Shows the current settings for ARP inspection on all interfaces.

    Monitoring the MAC Address Table

    You can view the entire MAC address table (including static and dynamic entries for both interfaces), or you can view the MAC address table for an interface. To view the MAC address table, enter the following command:

     

    Command
    Purpose
    show mac-address-table [ interface_name ]

    Shows the MAC address table.

    Examples

    The following is sample output from the show mac-address-table command that shows the entire table:

    hostname# show mac-address-table
    interface mac address type Time Left
    -----------------------------------------------------------------------
    outside 0009.7cbe.2100 static -
    inside 0010.7cbe.6101 static -
    inside 0009.7cbe.5101 dynamic 10
     

    The following is sample output from the show mac-address-table command that shows the table for the inside interface:

    hostname# show mac-address-table inside
    interface mac address type Time Left
    -----------------------------------------------------------------------
    inside 0010.7cbe.6101 static -
    inside 0009.7cbe.5101 dynamic 10
     

    Firewall Mode Examples

    This section includes examples of how traffic moves through the ASA and includes the following topics:

    How Data Moves Through the ASA in Routed Firewall Mode

    This section describes how data moves through the ASA in routed firewall mode and includes the following topics:

    An Inside User Visits a Web Server

    Figure 5-3 shows an inside user accessing an outside web server.

    Figure 5-3 Inside to Outside

     

    92404.jpg

    The following steps describe how data moves through the ASA (see Figure 5-3):

    1.blank.gif The user on the inside network requests a web page from www.example.com.

    2.blank.gif The ASA receives the packet and because it is a new session, the ASA verifies that the packet is allowed according to the terms of the security policy (access lists, filters, AAA).

    For multiple context mode, the ASA first classifies the packet to a context.

    3.blank.gif The ASA translates the local source address (10.1.2.27) to the global address 209.165.201.10, which is on the outside interface subnet.

    The global address could be on any subnet, but routing is simplified when it is on the outside interface subnet.

    4.blank.gif The ASA then records that a session is established and forwards the packet from the outside interface.

    5.blank.gif When www.example.com responds to the request, the packet goes through the ASA, and because the session is already established, the packet bypasses the many lookups associated with a new connection. The ASA performs NAT by untranslating the global destination address to the local user address, 10.1.2.27.

    6.blank.gif The ASA forwards the packet to the inside user.

    An Outside User Visits a Web Server on the DMZ

    Figure 5-4 shows an outside user accessing the DMZ web server.

    Figure 5-4 Outside to DMZ

     

    92406.jpg

    The following steps describe how data moves through the ASA (see Figure 5-4):

    1.blank.gif A user on the outside network requests a web page from the DMZ web server using the global destination address of 209.165.201.3, which is on the outside interface subnet.

    2.blank.gif The ASA receives the packet and untranslates the destination address to the local address 10.1.1.3.

    3.blank.gif Because it is a new session, the ASA verifies that the packet is allowed according to the terms of the security policy (access lists, filters, AAA).

    For multiple context mode, the ASA first classifies the packet to a context.

    4.blank.gif The ASA then adds a session entry to the fast path and forwards the packet from the DMZ interface.

    5.blank.gif When the DMZ web server responds to the request, the packet goes through the ASA and because the session is already established, the packet bypasses the many lookups associated with a new connection. The ASA performs NAT by translating the local source address to 209.165.201.3.

    6.blank.gif The ASA forwards the packet to the outside user.

    An Inside User Visits a Web Server on the DMZ

    Figure 5-5 shows an inside user accessing the DMZ web server.

    Figure 5-5 Inside to DMZ

     

    92403.jpg

    The following steps describe how data moves through the ASA (see Figure 5-5):

    1.blank.gif A user on the inside network requests a web page from the DMZ web server using the destination address of 10.1.1.3.

    2.blank.gif The ASA receives the packet and because it is a new session, the ASA verifies that the packet is allowed according to the terms of the security policy (access lists, filters, AAA).

    For multiple context mode, the ASA first classifies the packet to a context.

    3.blank.gif The ASA then records that a session is established and forwards the packet out of the DMZ interface.

    4.blank.gif When the DMZ web server responds to the request, the packet goes through the fast path, which lets the packet bypass the many lookups associated with a new connection.

    5.blank.gif The ASA forwards the packet to the inside user.

    An Outside User Attempts to Access an Inside Host

    Figure 5-6 shows an outside user attempting to access the inside network.

    Figure 5-6 Outside to Inside

     

    92407.jpg

    The following steps describe how data moves through the ASA (see Figure 5-6):

    1.blank.gif A user on the outside network attempts to reach an inside host (assuming the host has a routable IP address).

    If the inside network uses private addresses, no outside user can reach the inside network without NAT. The outside user might attempt to reach an inside user by using an existing NAT session.

    2.blank.gif The ASA receives the packet and because it is a new session, the ASA verifies if the packet is allowed according to the security policy (access lists, filters, AAA).

    3.blank.gif The packet is denied, and the ASA drops the packet and logs the connection attempt.

    If the outside user is attempting to attack the inside network, the ASA employs many technologies to determine if a packet is valid for an already established session.

    A DMZ User Attempts to Access an Inside Host

    Figure 5-7 shows a user in the DMZ attempting to access the inside network.

    Figure 5-7 DMZ to Inside

     

    92402.jpg

    The following steps describe how data moves through the ASA (see Figure 5-7):

    1.blank.gif A user on the DMZ network attempts to reach an inside host. Because the DMZ does not have to route the traffic on the Internet, the private addressing scheme does not prevent routing.

    2.blank.gif The ASA receives the packet and because it is a new session, the ASA verifies if the packet is allowed according to the security policy (access lists, filters, AAA).

    The packet is denied, and the ASA drops the packet and logs the connection attempt.

    How Data Moves Through the Transparent Firewall

    Figure 5-8 shows a typical transparent firewall implementation with an inside network that contains a public web server. The ASA has an access list so that the inside users can access Internet resources. Another access list lets the outside users access only the web server on the inside network.

    Figure 5-8 Typical Transparent Firewall Data Path

     

    92412.jpg

    This section describes how data moves through the ASA and includes the following topics:

    An Inside User Visits a Web Server

    Figure 5-9 shows an inside user accessing an outside web server.

    Figure 5-9 Inside to Outside

     

    92408.jpg

    The following steps describe how data moves through the ASA (see Figure 5-9):

    1.blank.gif The user on the inside network requests a web page from www.example.com.

    2.blank.gif The ASA receives the packet and adds the source MAC address to the MAC address table, if required. Because it is a new session, it verifies that the packet is allowed according to the terms of the security policy (access lists, filters, AAA).

    For multiple context mode, the ASA first classifies the packet to a context.

    3.blank.gif The ASA records that a session is established.

    4.blank.gif If the destination MAC address is in its table, the ASA forwards the packet out of the outside interface. The destination MAC address is that of the upstream router, 209.165.201.2.

    If the destination MAC address is not in the ASA table, the ASA attempts to discover the MAC address by sending an ARP request or a ping. The first packet is dropped.

    5.blank.gif The web server responds to the request; because the session is already established, the packet bypasses the many lookups associated with a new connection.

    6.blank.gif The ASA forwards the packet to the inside user.

    An Inside User Visits a Web Server Using NAT

    Figure 5-10 shows an inside user accessing an outside web server.

    Figure 5-10 Inside to Outside with NAT

     

    191243.jpg

    The following steps describe how data moves through the ASA (see Figure 5-10):

    1.blank.gif The user on the inside network requests a web page from www.example.com.

    2.blank.gif The ASA receives the packet and adds the source MAC address to the MAC address table, if required. Because it is a new session, it verifies that the packet is allowed according to the terms of the security policy (access lists, filters, AAA).

    For multiple context mode, the ASA first classifies the packet according to a unique interface.

    3.blank.gif The ASA translates the real address (10.1.2.27) to the mapped address 209.165.201.10.

    Because the mapped address is not on the same network as the outside interface, then be sure the upstream router has a static route to the mapped network that points to the ASA.

    4.blank.gif The ASA then records that a session is established and forwards the packet from the outside interface.

    5.blank.gif If the destination MAC address is in its table, the ASA forwards the packet out of the outside interface. The destination MAC address is that of the upstream router, 10.1.2.1.

    If the destination MAC address is not in the ASA table, the ASA attempts to discover the MAC address by sending an ARP request and a ping. The first packet is dropped.

    6.blank.gif The web server responds to the request; because the session is already established, the packet bypasses the many lookups associated with a new connection.

    7.blank.gif The ASA performs NAT by untranslating the mapped address to the real address, 10.1.2.27.

    An Outside User Visits a Web Server on the Inside Network

    Figure 5-11 shows an outside user accessing the inside web server.

    Figure 5-11 Outside to Inside

     

    92409.jpg

    The following steps describe how data moves through the ASA (see Figure 5-11):

    1.blank.gif A user on the outside network requests a web page from the inside web server.

    2.blank.gif The ASA receives the packet and adds the source MAC address to the MAC address table, if required. Because it is a new session, it verifies that the packet is allowed according to the terms of the security policy (access lists, filters, AAA).

    For multiple context mode, the ASA first classifies the packet to a context.

    3.blank.gif The ASA records that a session is established.

    4.blank.gif If the destination MAC address is in its table, the ASA forwards the packet out of the inside interface. The destination MAC address is that of the downstream router, 209.165.201.1.

    If the destination MAC address is not in the ASA table, the ASA attempts to discover the MAC address by sending an ARP request and a ping. The first packet is dropped.

    5.blank.gif The web server responds to the request; because the session is already established, the packet bypasses the many lookups associated with a new connection.

    6.blank.gif The ASA forwards the packet to the outside user.

    An Outside User Attempts to Access an Inside Host

    Figure 5-12 shows an outside user attempting to access a host on the inside network.

    Figure 5-12 Outside to Inside

     

    92410.jpg

    The following steps describe how data moves through the ASA (see Figure 5-12):

    1.blank.gif A user on the outside network attempts to reach an inside host.

    2.blank.gif The ASA receives the packet and adds the source MAC address to the MAC address table, if required. Because it is a new session, it verifies if the packet is allowed according to the terms of the security policy (access lists, filters, AAA).

    For multiple context mode, the ASA first classifies the packet to a context.

    3.blank.gif The packet is denied because there is no access list permitting the outside host, and the ASA drops the packet.

    4.blank.gif If the outside user is attempting to attack the inside network, the ASA employs many technologies to determine if a packet is valid for an already established session.

    Feature History for the Firewall Mode

    Table 5-2 lists each feature change and the platform release in which it was implemented.

     

    Table 5-2 Feature History for the Firewall Mode

    Feature Name
    Platform Releases
    Feature Information

    Transparent Firewall Mode

    7.0(1)

    A transparent firewall is a Layer 2 firewall that acts like a “bump in the wire,” or a “stealth firewall,” and is not seen as a router hop to connected devices.

    We introduced the following commands: firewall transparent, show firewall.

    ARP inspection

    7.0(1)

    ARP inspection compares the MAC address, IP address, and source interface in all ARP packets to static entries in the ARP table.

    We introduced the following commands: arp, arp-inspection, and show arp-inspection.

    MAC address table

    7.0(1)

    Transparent firewall mode uses a MAC address table.

    We introduced the following commands: mac-address-table static, mac-address-table aging-time, mac-learn disable, and show mac-address-table.

    Transparent firewall bridge groups

    8.4(1)

    If you do not want the overhead of security contexts, or want to maximize your use of security contexts, you can group interfaces together in a bridge group, and then configure multiple bridge groups, one for each network. Bridge group traffic is isolated from other bridge groups. You can configure up to 8 bridge groups in single mode or per context in multiple mode, with 4 interfaces maximum per bridge group.

    Note Although you can configure multiple bridge groups on the ASA 5505, the restriction of 2 data interfaces in transparent mode on the ASA 5505 means you can only effectively use 1 bridge group.

    We introduced the following commands: interface bvi, bridge-group, show bridge-group.