Manual Chapter : Using CGNAT Translation Modes

Applies To:

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BIG-IP LTM

  • 15.0.1, 15.0.0, 14.1.3, 14.1.2, 14.1.0
Manual Chapter

Using CGNAT Translation Modes

Overview: Using NAPT address translation mode

NAPT mode provides standard address and port translation allowing multiple clients in a private network to access remote networks using the single IP address assigned to their router. For outbound packets, NAPT translates the source IP address and source transport identifier. For inbound packets, NAPT translates the destination IP address, the destination transport identifier, and the IP and transport header checksums. This mode is beneficial for remote access users.

Task summary

NAPT log examples

The following examples describe typical NAPT log messages

NAT44 example

Mar 27 11:17:39 10.10.10.200 lsn_event="LSN_ADD",cli="10.10.10.1: 33950",nat="5.5.5.1:10000" Mar 27 11:17:39 10.10.10.200 "LSN_ADD""10.10.10.1: 33950""5.5.5.1:10000" Mar 27 11:23:17 localhost info tmm[32683]: "LSN_ADD""10.10.10.1:33950""5.5.5.1:10000" Mar 27 11:17:39 10.10.10.200 lsn_event="LSN_DELETE",cli="10.10.10.1: 33950",nat="5.5.5.1:10000" Mar 27 11:17:39 10.10.10.200 "LSN_DELETE""10.10.10.1: 33950""5.5.5.1:10000" Mar 27 11:23:17 localhost info tmm[32683]: "LSN_DELETE""10.10.10.1:33950""5.5.5.1:10000"

NAT44 example with route domains

Mar 28 08:34:12 10.10.21.200 lsn_event="LSN_ADD",cli="10.10.10.1%11: 59187",nat="5.5.5.1%22:10000" Mar 28 08:34:12 10.10.21.200 "LSN_ADD""10.10.10.1%11: 59187""5.5.5.1%22:10000" Mar 28 08:34:12 10.10.21.200 lsn_event="LSN_DELETE",cli="10.10.10.1%11: 59187",nat="5.5.5.1%22:10000" Mar 28 08:34:12 10.10.21.200 "LSN_DELETE""10.10.10.1%11: 59187""5.5.5.1%22:10000"

NAT64 example

Mar 27 11:18:20 10.10.10.200 lsn_event="LSN_ADD",cli="2701: 1:12:123:1234:432:43:100.39900",nat="5.5.5.1:10000" Mar 27 11:18:20 10.10.10.200 "LSN_ADD""2701: 1:12:123:1234:432:43:100.39900""5.5.5.1:10000" Mar 27 11:23:57 localhost info tmm[32683]: "LSN_ADD""2701:1:12:123:1234:432:43:100.39900""5.5.5.1:10000" Mar 27 11:18:23 10.10.10.200 lsn_event="LSN_DELETE",cli="2701: 1:12:123:1234:432:43:100.39900",nat="5.5.5.1:10000" Mar 27 11:18:23 10.10.10.200 "LSN_DELETE""2701: 1:12:123:1234:432:43:100.39900""5.5.5.1:10000" Mar 27 11:24:00 localhost info tmm[32683]: "LSN_DELETE""2701:1:12:123:1234:432:43:100.39900""5.5.5.1:10000"

NAT64 example with route domains

Mar 28 14:50:56 10.10.21.200 lsn_event="LSN_ADD",cli="2701: 1:12:123:1234:432:43:100%11.45000",nat="5.5.5.1%22:10000" Mar 28 14:50:56 10.10.21.200 "LSN_ADD""2701: 1:12:123:1234:432:43:100%11.45000""5.5.5.1%22:10000" Mar 28 14:50:56 10.10.21.200 lsn_event="LSN_DELETE",cli="2701: 1:12:123:1234:432:43:100%11.45000",nat="5.5.5.1%22:10000" Mar 28 14:50:56 10.10.21.200 "LSN_DELETE""2701: 1:12:123:1234:432:43:100%11.45000""5.5.5.1%22:10000"

NAT DSLITE

Mar 27 11:19:14 10.10.10.200 lsn_event="LSN_ADD",cli="10.10.31.4: 52240",nat="5.5.5.1:10000",dslite="2701::200" Mar 27 11:19:14 10.10.10.200 "LSN_ADD""10.10.31.4: 52240""5.5.5.1:10000""2701::200" Mar 27 11:24:52 localhost info tmm[32682]: "LSN_ADD""10.10.31.4:52240""5.5.5.1:10000""2701::200" Mar 27 11:19:18 10.10.10.200 lsn_event="LSN_DELETE",cli="10.10.31.4: 52240",nat="5.5.5.1:10000",dslite="2701::200" Mar 27 11:19:18 10.10.10.200 "LSN_DELETE""10.10.31.4: 52240""5.5.5.1:10000""2701::200" Mar 27 11:24:55 localhost info tmm[32682]: "LSN_DELETE""10.10.31.4:52240""5.5.5.1:10000""2701::200"

NAT DSLITE with route domains

Mar 28 15:03:40 10.10.21.200 lsn_event="LSN_ADD",cli="10.10.31.4%11: 51942",nat="5.5.5.1%22:10000",dslite="2701::200%11" Mar 28 15:03:40 10.10.21.200 "LSN_ADD""10.10.31.4%11: 51942""5.5.5.1%22:10000""2701::200%11" Mar 28 15:03:40 10.10.21.200 lsn_event="LSN_DELETE",cli="10.10.31.4%11: 51942",nat="5.5.5.1%22:10000",dslite="2701::200%11" Mar 28 15:03:40 10.10.21.200 "LSN_DELETE""10.10.31.4%11: 51942""5.5.5.1%22:10000""2701::200%11"

NAPT log examples with timestamp

The following examples describe typical NAPT log messages with timestamp.

HSL raw messages example

"LSN_ADD""10.10.10.15:51326""TCP""5.5.5.0:80""1436465636143" "LSN_DELETE""10.10.10.15:51326""TCP""5.5.5.0:80""1436465636143""4" "LSN_ADD""10.10.10.15:51326""UDP""5.5.5.0:514""1436465636143" "LSN_DELETE""10.10.10.15:51326""UDP""5.5.5.0:514""1436465636143""4" "LSN_ADD""10.10.10.15:51326""ICMP""5.5.5.0:0""1436465636143" "LSN_DELETE""10.10.10.15:51326""ICMP""5.5.5.0:0""1436465636143""4"

Splunk raw messages example

ip_protocol="TCP",lsn_event="LSN_ADD",start="1436465636143", cli="10.10.10.15:51326",nat="5.5.5.0:80" ip_protocol="TCP",lsn_event="LSN_DELETE",start="1436465636143", cli="10.10.10.15:51326",nat="5.5.5.0:80",duration="4" ip_protocol="UDP",lsn_event="LSN_ADD",start="1436465636143", cli="10.10.10.15:51326",nat="5.5.5.0:514" ip_protocol="UDP",lsn_event="LSN_DELETE",start="1436465636143", cli="10.10.10.15:51326",nat="5.5.5.0:514",duration="4" ip_protocol="ICMP",lsn_event="LSN_ADD",start="1436465636143", cli="10.10.10.15:51326",nat="5.5.5.0:0" ip_protocol="ICMP",lsn_event="LSN_DELETE",start="1436465636143", cli="10.10.10.15:51326",nat="5.5.5.0:0",duration="4"

remote-syslog raw messages (RFC3164 format) example

<134>Jul 09 11:13:56 victoria-5 tmm[11075]: "LSN_ADD""10.10.10.15:51326""TCP""4.4.0.0:80""1436465636143" <134>Jul 09 11:13:56 victoria-5 tmm[11075]: "LSN_DELETE""10.10.10.15:51326""TCP""4.4.0.0:80""1436465636143""4" <134>Jul 09 11:13:56 victoria-5 tmm[11075]: "LSN_ADD""10.10.10.15:51326""UDP""4.4.0.0:514""1436465636143" <134>Jul 09 11:13:56 victoria-5 tmm[11075]: "LSN_DELETE""10.10.10.15:51326""UDP""4.4.0.0:514""1436465636143""4" <134>Jul 09 11:13:56 victoria-5 tmm[11075]: "LSN_ADD""10.10.10.15:51326""ICMP""4.4.0.0:0""1436465636143" <134>Jul 09 11:13:56 victoria-5 tmm[11075]: "LSN_DELETE""10.10.10.15:51326""ICMP""4.4.0.0:0""1436465636143""4"

Local syslog raw messages

'Jul 9 11:13:56 slot3/victoria-5 info tmm[11075]: "LSN_ADD""10.10.10.15:51326""TCP""4.4.0.0:80""1436465636143"' 'Jul 9 11:13:56 slot3/victoria-5 info tmm[11075]: "LSN_DELETE""10.10.10.15:51326""TCP""4.4.0.0:80""1436465636143""4" 'Jul 9 11:13:56 slot3/victoria-5 info tmm[11075]: "LSN_ADD""10.10.10.15:51326""UDP""4.4.0.0:514""1436465636143"' 'Jul 9 11:13:56 slot3/victoria-5 info tmm[11075]: "LSN_DELETE""10.10.10.15:51326""UDP""4.4.0.0:514""1436465636143""4" 'Jul 9 11:13:56 slot3/victoria-5 info tmm[11075]: "LSN_ADD""10.10.10.15:51326""ICMP""4.4.0.0:0""1436465636143"' 'Jul 9 11:13:56 slot3/victoria-5 info tmm[11075]: "LSN_DELETE""10.10.10.15:51326""ICMP""4.4.0.0:0""1436465636143""4"

Creating a NAPT LSN pool

  • The CGNAT module must be provisioned before LSN pools can be configured.
  • Before associating a LSN pool with a log publisher, ensure that at least one log publisher exists on the BIG-IP system.
Large Scale NAT
(LSN) pools are used by the CGNAT module to allow efficient configuration of translation prefixes and parameters.
  1. On the Main tab, click
    Carrier Grade NAT
    LSN Pools
    .
    The LSN Pool List screen opens.
  2. Click
    Create
    .
  3. In the
    Name
    field, type a unique name.
  4. In the
    Description
    field, type a description.
  5. Select
    NAPT
    for the pool's translation
    Mode
    .
  6. Click
    Finished
    .
Your NAPT LSN pool is now ready and you can continue to configure your CGNAT.

Creating a VLAN for NAT

VLANs
represent a logical collection of hosts that can share network resources, regardless of their physical location on the network. You create a VLAN to associate physical interfaces with that VLAN.
  1. On the Main tab, click
    Network
    VLANs
    .
    The VLAN List screen opens.
  2. Click
    Create
    .
    The New VLAN screen opens.
  3. In the
    Name
    field, type a unique name for the VLAN.
  4. In the
    Tag
    field, type a numeric tag, between 1-4094, for the VLAN, or leave the field blank if you want the BIG-IP system to automatically assign a VLAN tag.
    The VLAN tag identifies the traffic from hosts in the associated VLAN.
  5. For the
    Interfaces
    setting:
    1. From the
      Interface
      list, select an interface number or trunk name.
    2. From the
      Tagging
      list, select
      Tagged
      or
      Untagged
      .
      Select
      Tagged
      when you want traffic for that interface to be tagged with a VLAN ID.
    3. If you specified a numeric value for the
      Customer Tag
      setting and from the
      Tagging
      list you selected
      Tagged
      , then from the
      Tag Mode
      list, select a value.
    4. Click
      Add
      .
    5. Repeat these steps for each interface or trunk that you want to assign to the VLAN.
  6. From the
    Configuration
    list, select
    Advanced
    .
  7. If you want the system to verify that the return route to an initial packet is the same VLAN from which the packet originated, select the
    Source Check
    check box.
  8. In the
    MTU
    field, retain the default number of bytes (
    1500
    ).
  9. If you want to base redundant-system failover on VLAN-related events, select the
    Fail-safe
    check box.
  10. From the
    Auto Last Hop
    list, select a value.
  11. From the
    CMP Hash
    list, select
    Source
    if this VLAN is the subscriber side or
    Destination Address
    if this VLAN is the Internet side.
  12. To enable the
    DAG Round Robin
    setting, select the check box.
  13. For the
    Hardware SYN Cookie
    setting, select or clear the check box.
    When you enable this setting, the BIG-IP system triggers hardware SYN cookie protection for this VLAN.
    Enabling this setting causes additional settings to appear. These settings appear on specific BIG-IP platforms only.
  14. For the
    Syncache Threshold
    setting, retain the default value or change it to suit your needs.
    The
    Syncache Threshold
    value represents the number of outstanding SYN flood packets on the VLAN that will trigger the hardware SYN cookie protection feature.
    When the
    Hardware SYN Cookie
    setting is enabled, the BIG-IP system triggers SYN cookie protection in either of these cases, whichever occurs first:
    • The number of TCP half-open connections defined in the LTM setting
      Global SYN Check Threshold
      is reached.
    • The number of SYN flood packets defined in this
      Syncache Threshold
      setting is reached.
  15. For the
    SYN Flood Rate Limit
    setting, retain the default value or change it to suit your needs.
    The
    SYN Flood Rate Limit
    value represents the maximum number of SYN flood packets per second received on this VLAN before the BIG-IP system triggers hardware SYN cookie protection for the VLAN.
  16. Click
    Finished
    .
    The screen refreshes, and it displays the new VLAN in the list.
You now have one of two VLANs for your deterministic or PBA NAT. Repeat these steps to create a second VLAN to act as the destination if the first VLAN is the source or vice versa.

Creating a NAT64 virtual server for an LSN pool

Virtual servers are matched based on source (client) addresses. Define a NAT64 virtual server that references the CGNAT profile and the LSN pool.
  1. On the Main tab, click
    Carrier Grade NAT
    Virtual Servers
    .
    The Virtual Server List screen opens.
  2. Click
    Create
    .
    The New Virtual Server screen opens.
  3. In the
    Name
    field, type a unique name for the virtual server.
  4. From the
    Type
    list, select
    Performance (Layer 4)
    .
  5. In the
    Destination Address
    field, type the IPv6 address in CIDR format.
    The supported format is address/prefix, where the prefix length is in bits. For example, an IPv6 address/prefix is
    64:ff9b::/64
    or
    2001:ed8:77b5:2::/64
    .
  6. In the
    Service Port
    field, type
    *
    or select
    * All Ports
    from the list.
  7. From the
    Configuration
    list, select
    Advanced
    .
  8. From the
    Protocol
    list, select
    * All Protocols
    .
  9. For the
    LSN Pool
    setting, select the pool that this server will draw on for translation addresses.
  10. For the
    Address Translation
    setting, select the
    Enabled
    check box to enable address translation.
  11. For the
    Port Translation
    setting, clear the
    Enabled
    check box.
  12. For the
    NAT64
    setting, select the
    Enabled
    check box.
  13. In the Resources area of the screen, for the
    iRules
    setting, select the name of the iRule that you want to assign and using the Move button, move the name from the
    Available
    list to the
    Enabled
    list.
  14. Click
    Finished
    .
The custom CGNAT NAT64 virtual server now appears in the CGNAT Virtual Servers list.

Overview: Using PBA mode to reduce CGNAT logging

Port block allocation (PBA) mode is a translation mode option that reduces CGNAT logging, by logging only the allocation and release of each block of ports. When a subscriber first establishes a network connection, the BIG-IP system reserves a block of ports on a single IP address for that subscriber. The system releases the block when no more connections are using it. This reduces the logging overhead because the CGNAT logs only the allocation and release of each block of ports.
When a subscriber first connects, the PBA translation mode applies client port block limits, which the subscriber uses as long as it has addresses allocated. For each subscriber, PBA mode compares the subscriber's allocated number of port blocks to the port block limit for the currently connected pool. If the allocated number of port blocks exceeds the port block limit, then the connection is denied. For example, if a subscriber's allocated number of port blocks is 2, and the port block limit for the currently connected pool is 1, then the connection is denied.

Task summary

About PBA address translation mode

Port Block Allocation (PBA) mode
provides you with the ability to log only the allocation and release of port blocks for a subscriber, instead of separately logging each network address translation (NAT) session as a separate translation event, as with network address and port translation (NAPT), thus reducing the number of log entries while maintaining legal mapping and reverse mapping requirements.

Restrictions

Configuration restrictions for PBA mode include these constraints.
  • PBA mode is compatible only with SP-DAG. If a VLAN is used that is not compatible with SP-DAG, then NAPT mode becomes active and an error is logged.
  • You can configure overlapping LSN prefixes only between pools of the same type. LSN prefixes are not overlapping when the port ranges for the prefixes do not overlap.
  • The system allocates one primary port block for each subscriber, with the allocation of an additional overflow port block, as necessary.
  • The Client Connection Limit (CCL) value constrains the number of subscriber connections, preventing any one subscriber from using an excessive number of connections.
  • PBA mode is available with NAT44, NAT64, and DS-Lite.

Behavior Characteristics

PBA mode manages connections by means of the following characteristics.
  • Port allocation within an active port block occurs until all available ports become allocated, or until the Block Lifetime limit is exceeded.
  • The Block Idle Timeout value specifies the period between when the last connection using a port block is freed and when the port block can be reused.
A
zombie port block
, which is a port block that has reached the Block Lifetime limit but cannot be released due to active connections, is released when all active connections become inactive, or when the Zombie Timeout value is reached.

Reduced Logging

When you use PBA mode, a log entry is sent when a block of ports is allocated for a subscriber, and again when a block of ports is released. Log entries include the range of ports (that is, the port block) from the start port through the end port. Several logging destinations are available for PBA mode, including Syslog, Splunk, and IPFIX.

About configuring PBA mode with route domains

Port block allocation (PBA) mode can be used with route domains to configure multiple subscriber networks in separate route domains. You can also partition subscriber networks and the Internet by using route domains.
A route domain that is used for the translation entry is not the subscriber route domain. The subscriber route domain is, instead, applied to the egress interface.
In the following configuration, multiple subscribers can connect to servers in Internet route domain 0. The BIG-IP system allocates, to each subscriber, available port blocks from Internet route domain 0 that include unique addresses and ports.
Multiple subscriber networks connecting to Internet servers in Internet Route Domain 0
Multiple subscriber networks connecting to Internet servers in Internet Route Domain     0
In the next configuration, multiple subscribers can connect to servers in respective Internet route domains. The BIG-IP system allocates available port blocks from the respective Internet route domain to the corresponding subscriber. Allocated port blocks can differ only by route domain, and use identical address and port ranges; consequently, for this configuration, a service provider must provide a means to distinguish the connections of different route domains, as necessary.
Multiple subscriber networks connecting to Internet servers in separate Internet route domains
Multiple subscriber networks connecting to Internet servers in separate Internet route     domains

PBA log examples

Following are some examples of the elements that comprise a typical Port Block Allocation (PBA) mode log entry.
PBA log messages include several elements of interest. The following examples show typical log messages, and the table describes common information types.

NAT44 HSL example

Jul 23 09:33:42 www.siterequest.com "LSN_PB_ALLOCATED""10.10.10.1""5.5.5.9: 5555-6666" Jul 23 09:33:42 www.siterequest.com "LSN_PB_RELEASED""10.10.10.1""5.5.5.9: 5555-6666"

NAT44 HSL with route domains example

Jul 23 09:33:42 www.siterequest.com "LSN_PB_ALLOCATED""10.10.10.1%55""5.5.5.9%22: 5555-6666" Jul 23 09:33:42 www.siterequest.com "LSN_PB_RELEASED""10.10.10.1%55""5.5.5.9%22: 5555-6666"

DS-Lite HSL example

Jul 23 10:46:31 www.siterequest.com "LSN_PB_ALLOCATED""2701: :200""5.5.5.9:5555-6666" Jul 23 10:46:31 www.siterequest.com "LSN_PB_RELEASED""2701: :200""5.5.5.9:5555-6666"

DS-Lite HSL with route domains example

Jul 23 09:36:33 www.siterequest.com "LSN_PB_ALLOCATED""2701: :200%11""5.5.5.9%22:5555-6666" Jul 23 09:36:33 www.siterequest.com "LSN_PB_RELEASED""2701: :200%11""5.5.5.9%22:5555-6666"

NAT64 HSL example

Jul 23 09:36:33 www.siterequest.com "LSN_PB_ALLOCATED""2701: :200""5.5.5.9:5555-6666" Jul 23 09:36:33 www.siterequest.com "LSN_PB_RELEASED""2701: :200"5.5.5.9:5555-6666"

NAT64 HSL with route domains example

Jul 23 09:36:33 www.siterequest.com "LSN_PB_ALLOCATED""2701: :200%33""5.5.5.9%22:5555-6666" Jul 23 09:36:33 www.siterequest.com "LSN_PB_RELEASED""2701: :200%33""5.5.5.9%22:5555-6666"

NAT44 Splunk example

Jul 23 10:56:13 www.siterequest.com lsn_event="LSN_PB_ALLOCATED",lsn_client="10.10.10.1",lsn_pb="5.5.5.9: 5555-6666" Jul 23 10:56:13 www.siterequest.com lsn_event="LSN_PB_RELEASED",lsn_client="10.10.10.1",lsn_pb="5.5.5.9: 5555-6666"

NAT44 Splunk with route domains example

Jul 23 10:56:13 www.siterequest.com lsn_event="LSN_PB_ALLOCATED",lsn_client="10.10.10.1%55",lsn_pb="5.5.5.9%22: 5555-6666" Jul 23 10:56:13 www.siterequest.com lsn_event="LSN_PB_RELEASED",lsn_client="10.10.10.1%55",lsn_pb="5.5.5.9%22: 5555-6666"

DS-Lite Splunk example

Jul 23 10:57:08 www.siterequest.com lsn_event="LSN_PB_ALLOCATED",lsn_dslite_client="2701: :200",lsn_pb="5.5.5.9:5555-6666" Jul 23 10:57:08 www.siterequest.com lsn_event="LSN_PB_RELEASED",lsn_dslite_client="2701: :200",lsn_pb="5.5.5.9:5555-6666"

DS-Lite Splunk with route domains example

Jul 23 10:57:08 www.siterequest.com lsn_event="LSN_PB_ALLOCATED",lsn_dslite_client="2701: :200%11",lsn_pb="5.5.5.9%22:5555-6666" Jul 23 10:57:08 www.siterequest.com lsn_event="LSN_PB_RELEASED",lsn_dslite_client="2701: :200%11",lsn_pb="5.5.5.9%22:5555-6666"

NAT64 Splunk example

Jul 23 10:57:08 www.siterequest.com lsn_event="LSN_PB_ALLOCATED",lsn_client="2701: :200",lsn_pb="5.5.5.9:5555-6666" Jul 23 10:57:08 www.siterequest.com lsn_event="LSN_PB_RELEASED",lsn_client="2701: :200",lsn_pb="5.5.5.9:5555-6666"

NAT64 Splunk with route domains example

Jul 23 10:57:08 www.siterequest.com lsn_event="LSN_PB_ALLOCATED",lsn_client="2701: :200%33",lsn_pb="5.5.5.9%22:5555-6666" Jul 23 10:57:08 www.siterequest.com lsn_event="LSN_PB_RELEASED",lsn_client="2701: :200%33",lsn_pb="5.5.5.9%22:5555-6666"
Information Type
Example Value
Description
Timestamp
Jul 23 10:57:08
Specifies the time and date that the system logged the event message.
Domain name
www.siterequest.com
Specifies the domain name of the client.
LSN event
lsn_event="LSN_PB_ALLOCATED"
;
lsn_event="LSN_PB_RELEASED"
Specifies the allocation or release of the port block.
Client address
10.10.10.1
;
10.10.10.1%55
;
2701: :200
;
2701: :200%33
;
lsn_client="10.10.10.1"
;
lsn_client="10.10.10.1%55"
;
lsn_dslite_client="2701: :200"
;
lsn_dslite_client="2701: :200%11"
Specifies the address of the client.
Port block address
5.5.5.9
;
5.5.5.9%22
Specifies the address of the port block.
Port range start
5555
Specifies the start of the port range.
Port range end
6666
Specifies the end of the port range.

Creating a PBA LSN pool

  • The CGNAT module must be provisioned before LSN pools can be configured.
  • Before associating a LSN pool with a log publisher, ensure that at least one log publisher exists on the BIG-IP system.
You configure
Large Scale NAT
(LSN) pools for the CGNAT module to use in allowing efficient configuration of translation prefixes and parameters.
  1. On the Main tab, click
    Carrier Grade NAT
    LSN Pools
    .
    The LSN Pool List screen opens.
  2. Click
    Create
    .
  3. In the
    Name
    field, type a unique name.
  4. In the
    Description
    field, type a description.
  5. For the
    Mode
    setting, select
    PBA
    for the pool's translation.
    Note that PBA mode for DS-lite is same as for NAT44, except that all clients behind the DS-Lite tunnel are managed as one subscriber. Port block limits are in accordance with each DS-lite tunnel.
  6. For the
    Port Block Allocation
    setting, specify your preferred PBA configuration.
    1. In the
      Block Size
      field, type the number of ports designated for a block.
    2. In the
      Block Lifetime
      field, type the number of seconds before a port block times out.
      If you type a timeout other than
      0
      , you can also specify a
      Zombie Timeout
      . A
      Block Lifetime
      value that is less than the
      Persistence Timeout
      value minimizes the number of zombie port blocks. The default value of
      0
      specifies no lifetime limit and indefinite use of the port block.
    3. In the
      Block Idle Timeout
      field, enter the timeout (in seconds) for after the port block becomes idle.
      Typically, you want to use a
      Block Idle Timeout
      value less than the
      Persistence Timeout
      value, to minimize the number of zombie port blocks.
    4. In the
      Client Block Limit
      field, type the number of blocks that can be assigned to a single subscriber IP address.
    5. In the
      Zombie Timeout
      field, type the number of seconds before port block times out.
      A
      zombie port block
      is a timed out port block with one or more active connections. The default value of
      0
      specifies no timeout and an indefinite zombie state for the port block, as long as connections remain active. A value other than
      0
      specifies a timeout expiration, upon which existing connections are terminated, and the port block is released and returned to the pool.
  7. In the Configuration area, for the
    Member List
    setting, type an address and a prefix length in the
    Address/Prefix Length
    field, and click
    Add
    .
  8. Click
    Finished
    .
Your PBA LSN pool is now ready, and you can continue to configure your CGNAT.

Creating a VLAN for NAT

VLANs
represent a logical collection of hosts that can share network resources, regardless of their physical location on the network. You create a VLAN to associate physical interfaces with that VLAN.
  1. On the Main tab, click
    Network
    VLANs
    .
    The VLAN List screen opens.
  2. Click
    Create
    .
    The New VLAN screen opens.
  3. In the
    Name
    field, type a unique name for the VLAN.
  4. In the
    Tag
    field, type a numeric tag, between 1-4094, for the VLAN, or leave the field blank if you want the BIG-IP system to automatically assign a VLAN tag.
    The VLAN tag identifies the traffic from hosts in the associated VLAN.
  5. For the
    Interfaces
    setting:
    1. From the
      Interface
      list, select an interface number or trunk name.
    2. From the
      Tagging
      list, select
      Tagged
      or
      Untagged
      .
      Select
      Tagged
      when you want traffic for that interface to be tagged with a VLAN ID.
    3. If you specified a numeric value for the
      Customer Tag
      setting and from the
      Tagging
      list you selected
      Tagged
      , then from the
      Tag Mode
      list, select a value.
    4. Click
      Add
      .
    5. Repeat these steps for each interface or trunk that you want to assign to the VLAN.
  6. From the
    Configuration
    list, select
    Advanced
    .
  7. If you want the system to verify that the return route to an initial packet is the same VLAN from which the packet originated, select the
    Source Check
    check box.
  8. In the
    MTU
    field, retain the default number of bytes (
    1500
    ).
  9. If you want to base redundant-system failover on VLAN-related events, select the
    Fail-safe
    check box.
  10. From the
    Auto Last Hop
    list, select a value.
  11. From the
    CMP Hash
    list, select
    Source
    if this VLAN is the subscriber side or
    Destination Address
    if this VLAN is the Internet side.
  12. To enable the
    DAG Round Robin
    setting, select the check box.
  13. For the
    Hardware SYN Cookie
    setting, select or clear the check box.
    When you enable this setting, the BIG-IP system triggers hardware SYN cookie protection for this VLAN.
    Enabling this setting causes additional settings to appear. These settings appear on specific BIG-IP platforms only.
  14. For the
    Syncache Threshold
    setting, retain the default value or change it to suit your needs.
    The
    Syncache Threshold
    value represents the number of outstanding SYN flood packets on the VLAN that will trigger the hardware SYN cookie protection feature.
    When the
    Hardware SYN Cookie
    setting is enabled, the BIG-IP system triggers SYN cookie protection in either of these cases, whichever occurs first:
    • The number of TCP half-open connections defined in the LTM setting
      Global SYN Check Threshold
      is reached.
    • The number of SYN flood packets defined in this
      Syncache Threshold
      setting is reached.
  15. For the
    SYN Flood Rate Limit
    setting, retain the default value or change it to suit your needs.
    The
    SYN Flood Rate Limit
    value represents the maximum number of SYN flood packets per second received on this VLAN before the BIG-IP system triggers hardware SYN cookie protection for the VLAN.
  16. Click
    Finished
    .
    The screen refreshes, and it displays the new VLAN in the list.
You now have one of two VLANs for your deterministic or PBA NAT. Repeat these steps to create a second VLAN to act as the destination if the first VLAN is the source or vice versa.

Creating a virtual server for an LSN pool

Virtual servers are matched based on source (client) addresses. Define a virtual server that references the CGNAT profile and the LSN pool.
  1. On the Main tab, click
    Carrier Grade NAT
    Virtual Servers
    .
    The Virtual Server List screen opens.
  2. Click
    Create
    .
    The New Virtual Server screen opens.
  3. In the
    Name
    field, type a unique name for the virtual server.
  4. From the
    Type
    list, select
    Performance (Layer 4)
    .
  5. For a network, in the
    Destination Address
    field, type an IPv4 or IPv6 address in CIDR format to allow all traffic to be translated.
    The supported format is address/prefix, where the prefix length is in bits. For example, an IPv4 address/prefix is
    0.0.0.0/0
    , and an IPv6 address/prefix is
    ::/0
    .
  6. In the
    Service Port
    field, type
    *
    or select
    * All Ports
    from the list.
  7. From the
    VLAN and Tunnel Traffic
    list, select
    Enabled on
    . Then, for the
    VLANs and Tunnels
    setting, move the VLAN or VLANs on which you want to allow the virtual servers to share traffic from the
    Available
    list to the
    Selected
    list.
  8. For the
    LSN Pool
    setting, select the pool that this server will draw on for translation addresses.
  9. In the Resources area of the screen, for the
    iRules
    setting, select the name of the iRule that you want to assign and using the Move button, move the name from the
    Available
    list to the
    Enabled
    list.
  10. Click
    Finished
    .
The custom CGNAT virtual server now appears in the CGNAT Virtual Servers list.

Overview: Deterministic address translation mode

Deterministic address translation mode
provides address translation that eliminates logging of every address mapping, while still allowing internal client address tracking using only an external address and port, and a destination address and port. Reverse mapping allows BIG-IP CGNAT operators to respond to legal requests revealing the identity of the originator of a specific communication. A typical example is revealing the identity of file sharers or P2P network users accused of copyright theft.
Deterministic mode allows unique identification of internal client address based on:
  • External address and port (the address and port visible to the destination server)
  • Destination address and port (the service accessed by the client)
  • Time

Restrictions

Deterministic mode has these configuration restrictions:
  • Only NAT44 can use deterministic mode.
  • The subscriber (client-side) and Internet (server-side) interfaces (VLANs) must be set either as a source or destination address in the
    CMP Hash
    setting.
  • The complete set of all internal client addresses that will ever communicate through the CGNAT must be entered at configuration time.
    This means that all virtual servers referring to an LSN pool through deterministic NAT mode must specify the source attribute with a value other than 0.0.0.0/0 or ::/0 (any/0, any6/0).
  • Use only the most specific address prefixes covering all customer addresses.
  • Members of two or more deterministic LSN pools must not overlap; in other words, every external address used for deterministic mapping must occur in only one LSN pool.
  • Deterministic mode does not support IPFIX.

Simplified logging

As an alternative to per-connection logging, deterministic mode maps internal addresses to external addresses algorithmically to calculate the mapping without relying on per-connection logging. Deterministic mode significantly reduces the logging burden while mapping a subscriber's inside IP address with an outside Internet address and port.
To decipher mapping generated by LSN pools using deterministic mode, you must use the DNAT utility that can be run from the system's
tmsh
command prompt.

Task summary

Creating a deterministic LSN pool

The CGNAT module must be provisioned before you can configure LSN pools.
Large Scale NAT
(LSN) pools are used by the CGNAT module to allow efficient configuration of translation prefixes and parameters.
  1. On the Main tab, click
    Carrier Grade NAT
    LSN Pools
    .
    The LSN Pool List screen opens.
  2. Click
    Create
    .
  3. In the
    Name
    field, type a unique name.
  4. For the
    Mode
    setting, select
    Deterministic
    for the pool's translation.
    Note that deterministic mode does not support
    DS-lite
    tunneling or
    NAT64
    .
  5. From the
    Log Publisher
    list, select the publisher that includes the destinations to which you want to send log messages.
  6. In the Configuration area, for the
    Member List
    setting, type an address and a prefix length in the
    Address/Prefix Length
    field, and click
    Add
    .
    If your pool uses deterministic mode, ensure that any address ranges you enter as a member do not overlap another member's prefix address ranges. For example, the address and prefix
    10.10.10.0/24
    overlaps
    10.10.10.0/23
    .
  7. For deterministic mode, the
    Backup Member List
    must have at least one member, so type an address in the
    Address/Prefix Length
    field and click
    Add
    .
  8. Click
    Finished
    .
Your deterministic LSN pool is now ready, and you can continue to configure your CGNAT.

Creating a VLAN for NAT

VLANs
represent a logical collection of hosts that can share network resources, regardless of their physical location on the network. You create a VLAN to associate physical interfaces with that VLAN.
  1. On the Main tab, click
    Network
    VLANs
    .
    The VLAN List screen opens.
  2. Click
    Create
    .
    The New VLAN screen opens.
  3. In the
    Name
    field, type a unique name for the VLAN.
  4. In the
    Tag
    field, type a numeric tag, between 1-4094, for the VLAN, or leave the field blank if you want the BIG-IP system to automatically assign a VLAN tag.
    The VLAN tag identifies the traffic from hosts in the associated VLAN.
  5. For the
    Interfaces
    setting:
    1. From the
      Interface
      list, select an interface number or trunk name.
    2. From the
      Tagging
      list, select
      Tagged
      or
      Untagged
      .
      Select
      Tagged
      when you want traffic for that interface to be tagged with a VLAN ID.
    3. If you specified a numeric value for the
      Customer Tag
      setting and from the
      Tagging
      list you selected
      Tagged
      , then from the
      Tag Mode
      list, select a value.
    4. Click
      Add
      .
    5. Repeat these steps for each interface or trunk that you want to assign to the VLAN.
  6. From the
    Configuration
    list, select
    Advanced
    .
  7. If you want the system to verify that the return route to an initial packet is the same VLAN from which the packet originated, select the
    Source Check
    check box.
  8. In the
    MTU
    field, retain the default number of bytes (
    1500
    ).
  9. If you want to base redundant-system failover on VLAN-related events, select the
    Fail-safe
    check box.
  10. From the
    Auto Last Hop
    list, select a value.
  11. From the
    CMP Hash
    list, select
    Source
    if this VLAN is the subscriber side or
    Destination Address
    if this VLAN is the Internet side.
  12. To enable the
    DAG Round Robin
    setting, select the check box.
  13. For the
    Hardware SYN Cookie
    setting, select or clear the check box.
    When you enable this setting, the BIG-IP system triggers hardware SYN cookie protection for this VLAN.
    Enabling this setting causes additional settings to appear. These settings appear on specific BIG-IP platforms only.
  14. For the
    Syncache Threshold
    setting, retain the default value or change it to suit your needs.
    The
    Syncache Threshold
    value represents the number of outstanding SYN flood packets on the VLAN that will trigger the hardware SYN cookie protection feature.
    When the
    Hardware SYN Cookie
    setting is enabled, the BIG-IP system triggers SYN cookie protection in either of these cases, whichever occurs first:
    • The number of TCP half-open connections defined in the LTM setting
      Global SYN Check Threshold
      is reached.
    • The number of SYN flood packets defined in this
      Syncache Threshold
      setting is reached.
  15. For the
    SYN Flood Rate Limit
    setting, retain the default value or change it to suit your needs.
    The
    SYN Flood Rate Limit
    value represents the maximum number of SYN flood packets per second received on this VLAN before the BIG-IP system triggers hardware SYN cookie protection for the VLAN.
  16. Click
    Finished
    .
    The screen refreshes, and it displays the new VLAN in the list.
You now have one of two VLANs for your deterministic or PBA NAT. Repeat these steps to create a second VLAN to act as the destination if the first VLAN is the source or vice versa.

Creating a virtual server for an LSN pool

Virtual servers are matched based on source (client) addresses. Define a virtual server that references the CGNAT profile and the LSN pool.
  1. On the Main tab, click
    Carrier Grade NAT
    Virtual Servers
    .
    The Virtual Server List screen opens.
  2. Click
    Create
    .
    The New Virtual Server screen opens.
  3. In the
    Name
    field, type a unique name for the virtual server.
  4. From the
    Type
    list, select
    Performance (Layer 4)
    .
  5. For a network, in the
    Destination Address
    field, type an IPv4 or IPv6 address in CIDR format to allow all traffic to be translated.
    The supported format is address/prefix, where the prefix length is in bits. For example, an IPv4 address/prefix is
    0.0.0.0/0
    , and an IPv6 address/prefix is
    ::/0
    .
  6. In the
    Service Port
    field, type
    *
    or select
    * All Ports
    from the list.
  7. From the
    VLAN and Tunnel Traffic
    list, select
    Enabled on
    . Then, for the
    VLANs and Tunnels
    setting, move the VLAN or VLANs on which you want to allow the virtual servers to share traffic from the
    Available
    list to the
    Selected
    list.
  8. For the
    LSN Pool
    setting, select the pool that this server will draw on for translation addresses.
  9. In the Resources area of the screen, for the
    iRules
    setting, select the name of the iRule that you want to assign and using the Move button, move the name from the
    Available
    list to the
    Enabled
    list.
  10. Click
    Finished
    .
The custom CGNAT virtual server now appears in the CGNAT Virtual Servers list.

Overview: The DNAT utility

BIG-IP deterministic NAT (DNAT) mode allows conservation of log storage for service providers by mapping subscribers to public translation addresses and ports algorithmically so that very little data needs to be stored in logs. The DNAT utility (
dnatutil
) is necessary for identifying subscribers through calculation of reverse source address and port mapping of deterministic-mode LSN pools, by using the states stored in the log files.
The DNAT utility can interpret logs from version 11.4.0 and later, correctly reverse mapping subscribers, or forward mapping possible end-points of the subscriber. DNAT, as of version 11.5 of the BIG-IP system, supports multiple log destinations including, LTM, Remote Syslog, and Splunk. The DNAT utility can parse logs from any supported DNAT log destination.
The DNAT utility binary can be run either on the BIG-IP system or on any supported Linux host. The DNAT utility package currently supports CentOS 64 and Ubuntu 64 for deployment on Linux systems to support reverse mappings on archived logs. The package is available from the F5 Downloads site (
http://support.f5.com/kb/en-us.html
).

Task summary

DNAT utility example commands

This list provides examples of the syntax used in commands for
dnatutil
.
Command
Response
dnatutil 10.0.0.1 --action forward
Shows a list of translation address/port pairs that might be used for a subscriber at 10.0.0.1, using the DNAT states contained in /var/log/ltm.
dnatutil 173.240.102.139:5678
Performs a reverse mapping back to the subscriber address for the connection from 173.240.102.139:5678, using the DNAT states contained in /var/log/ltm.
dnatutil --start_time ’2012-09-27 06:30:00’ --end_time ’2012-09-27 12:10:00’ 173.240.102.139:5678
Performs a reverse mapping back to the subscriber address for the connection from 173.240.102.139:5678, but only shows the subscriber addresses that used the translation within the specified time range.
dnatutil --start_time ’2012-09-27 06:30:00’ --end_time ’2012-09-27 12:10:00’ --file ltmlog-21102013 173.240.102.139:5678
Performs a reverse mapping back to the subscriber address for the connection from 173.240.102.139:5678, showing the subscriber addresses that used the translation within the specified time range, and using the DNAT states contained in /var/log/test.
dnatutil --file /var/log/test
Shows summary information, using the DNAT states contained in /var/log/test.
dnatutil --action summary --start_time ’2012-09-27 06:30:00’ --end_time ’2012-09-27 12:10:00’
Shows summary information, using the DNAT states within the specified time range.
dnatutil --action reverse_addr 1.2.3.4
Shows a list of possible subscriber addresses for the provided client address.
dnatutil --help | grep DAG_ID
Provides version information for the utility.

Downloading the DNAT utility external tool

The deterministic NAT (DNAT) reverse mapping tool can run independently from the BIG-IP system. Follow these steps to download the
dnatutil
RPM or Debian file from the F5 Downloads site.
  1. Access the F5 Downloads site at
    http://downloads.f5.com
    .
  2. From the Downloads Overview page, click
    Find a Download
    .
    The Select a Product Line page displays.
  3. Under
    Product Line
    , click the BIG-IP software branch
    BIG-IP v12.x
    .
  4. Select
    BIG-IP version 12.x
    from the drop-down menu.
    The system selects the most recent version of software, by default.
  5. From the Name column, select
    DNAT-Utility
    .
    A Software Terms and Conditions page appears.
  6. Read the End User Software License Agreement (EULA) and either accept the license by clicking
    I Accept
    , or cancel the process by clicking
    Cancel
    .
    If you accept the EULA, the Select a Download page appears with a table detailing the file name, product description, and size of the file. You should see three files:
    • dnatutil.rpm
    • dnatutil.deb
    • readme.txt
  7. Select the file you would like to download.
Now that you have downloaded the DNAT utility RPM/Debian package, you can now use
dnatutil
for forward and reverse mappings.

Using the DNAT utility external tool for reverse mappings

To discover the subscriber address, you need to have at least the NAT/public address you would like to translate. It is preferable to have the date, time, and NAT/public address, port, and the archived logs with the state information you wish to use.
Deterministic NATs (DNATs) can reduce total log file size but require use of the DNAT utility (
dnatutil
) to decipher the mapping. With
dnatutil
, you can calculate forward end-points and reverse client address and port mapping of an LSN pool using deterministic mode based on the state stored in the specified log file.
  1. Download the BIG-IP version 11.x RPM or Debian file from the F5 Downloads web site (
    https://downloads.f5.com
    ) to a preferred location.
  2. Using the command line, type
    install -Uvh <rpm>
    to install the RPM file.
  3. Type
    dnatutil
    with the date, time, NAT/public address, and port that you want to translate.
    dnatutil –-file /var/log/messages --start_time "2013-10-02 15:21:12" –-end_time "2013-10-02 15:22:42" 1.1.1.1:1234
  4. Press enter.
    If the BIG-IP platform is located in a different time zone than the receiving log server, messages might not be correctly interpreted.
    TZ
    is an environmental variable that specifies the timezone. If not specified, the local timezone is used.
    # dnatutil --file ltm 1.1.7.1:1025 From (1365014711): 2013-04-03 18:45:11 GMT Reverse mapping for ::,80 -> 1.1.7.1,1025 Using cmp-hash 'dst-ip' and TMM 1:10.10.10.11
    The log entry will show the source prefix, destination prefix (public address), and the subscriber IP address for the time range.
You now have the basic details for deciphering deterministic log files using the DNAT utility.

Using DNAT utility to look up deterministic NAT mappings on the BIG-IP system

You should know how to navigate in
tmsh
before using the DNAT utility (
dnatutil
). For detailed information about navigating in
tmsh
, see the
Traffic Management Shell (tmsh) Reference Guide
.
Deterministic NATs can reduce total log file size but require use of the
dnatutil
(available in
tmsh
) to decipher the mapping. With the
dnatutil
, you can calculate forward and reverse source address and port mapping of an LSN pool using deterministic mode based on the state stored in the specified TMM log file.
  1. Use an SSH tool to access the BIG-IP system from the command line.
  2. At the command line, type:
    tmsh
    .
    This starts
    tmsh
    in interactive shell mode and displays the prompt:
    (tmos)#
    .
  3. If you do not provide a file and you are on a BIG-IP system, it will default to the LTM log.
    To show a list of translation address/port pairs used for a subscriber at
    10.0.0.1:4321
    connecting to
    65.61.115.222:80
    , using the deterministic NAT states contained in
    /var/log/ltm
    , type the command:
    run util dnat --file /var/log/ltm --client_addr 10.0.0.1 --client_port 4321 --server_addr 65.61.115.222 --action forward
    Replace these example addresses with your actual client and server.
    This displays a list of the address/port pairs.
  4. To calculate a reverse mapping back to the subscriber address for the connection between 173.240.102.139:5678 and 65.61.115.222:80, using the DNAT states contained in
    /var/log/ltm.1
    , type the command:
    run util dnat --file /var/log/ltm.1 --server_addr 65.61.115.222 --client_addr 173.240.102.139 --client_port 5678 --action reverse
    This displays the reverse mapping.
  5. For more information about the DNAT utility, type the command:
    help util dnat
    at the
    tmsh
    prompt.
    The help file for the DNAT utility is displayed.
You now have the basic details for deciphering deterministic log files using the DNAT utility in
tmsh
.

Overview: PCP client address translation

Port Control Protocol (PCP) clients can request specific NAT/CGNAT mappings for themselves and/or for third-party devices. This allows the PCP clients to set their own public-side IP addresses (also called
translation addresses
) in a network that uses CGNAT. In cases where the BIG-IP system assigns a translation address or port other than the one requested, the client is at least aware of their assigned address or port.
You apply a PCP profile to a Large Scale NAT (LSN) pool of translation addresses. A client that uses the LSN pool can also send PCP requests to the BIG-IP system to request a particular address/port from the pool. RFC 6887 defines PCP.

Task summary

Creating a PCP profile

Someone must license the CGNAT module through
System
License
, and enable it through
System
Resource Provisioning
before you can create a PCP profile.
A PCP profile defines limitations for PCP-client requests.
  1. On the Main tab, click
    Carrier Grade NAT
    PCP Profiles
    +
    .
    The New PCP Profile screen opens.
  2. In the
    Name
    field, type a unique name.
  3. You can accept the defaults in this profile, or you can select the check box next to any setting that you want to change.
    The online help describes each field.
  4. Click
    Finished
    .
Your PCP profile is now ready to be used in one or more LSN pools.

Configuring an LSN pool with a PCP profile

An
LSN Pool
is a group of addresses and ports to be used as translation addresses by a virtual server's clients. If one of those clients sends a PCP request (for example, to map the client's private IP address to a particular translation address), the LSN pool's PCP profile determines the ranges and limits allowed for the request.
You assign a PCP profile to an LSN pool in the pool's configuration screen. You also designate the IP address and/or DS-Lite tunnel to which the virtual server's clients can send their PCP requests.
  1. On the Main tab, click
    Carrier Grade NAT
    LSN Pools
    .
    The LSN Pool List screen opens.
  2. Click the name of an LSN pool.
  3. From the
    PCP Profile
    list, select a pre-created PCP profile.
    If you have not yet created a customized profile, you can use the default PCP profile
    pcp
    .
    The other two PCP-related settings become active.
  4. Type a self IP address or a DS-Lite tunnel where the virtual server's clients can send their PCP requests. You can use either field:
    • Use the
      PCP Server IP
      list to select one of the existing self IP addresses on the system, or
    • Use the
      PCP DS-LITE Tunnel Name - IPv6
      list to select an existing DS-Lite tunnel
    The virtual server's clients can send PCP requests to the self-IP address or through the DS-Lite tunnel you selected.
After you perform this task, any virtual server with this LSN pool can support PCP. The virtual server's clients can send PCP MAP requests to the address or tunnel you specified here.
No client can use this PCP configuration unless the LSN pool is assigned to at least one virtual server. Go to
Carrier Grade NAT
Virtual Servers
Virtual Server List
for a list of servers. Look for the LSN pool's name in the
LSN Pool
column. Confirm that at least one virtual server uses this LSN pool.