============================================================================== PF: The OpenBSD Packet Filter ------------------------------------------------------------------------------ Table of Contents * Basic Configuration + Getting Started + Lists and Macros + Tables + Packet Filtering + Network Address Translation + Traffic Redirection (Port Forwarding) + Shortcuts For Creating Rulesets * Advanced Configuration + Runtime Options + Scrub (Packet Normalization) + Anchors and Named (Sub) Rulesets + Packet Queueing and Prioritization + Address Pools and Load Balancing + Packet Tagging * Additional Topics + Logging + Performance + Issues with FTP + Authpf: User Shell for Authenticating Gateways * Example Rulesets + Example: Firewall for Home or Small Office ------------------------------------------------------------------------------ Packet Filter (from here on referred to as PF) is OpenBSD's system for filtering TCP/IP traffic and doing Network Address Translation. PF is also capable of normalizing and conditioning TCP/IP traffic and providing bandwidth control and packet prioritization. PF has been a part of the GENERIC OpenBSD kernel since OpenBSD 3.0. Previous OpenBSD releases used a different firewall/ NAT package which is no longer supported. PF was originally developed by Daniel Hartmeier and is now maintained and developed by Daniel and the rest of the OpenBSD team. This set of documents is intended as a general introduction to the PF system as run on OpenBSD. It is intended to be used as a supplement to the man pages, not as a replacement for them. This document covers all of PF's major features. For a complete and in-depth view of what PF can do, please start by reading the pf(4) man page. As with the rest of the FAQ, this document is focused on users of OpenBSD 3.5. As PF is always growing and developing, there are changes and enhancements between the 3.5-release version and the version in OpenBSD-current. The reader is advised to see the man pages for the version of OpenBSD they are currently working with. ------------------------------------------------------------------------------ $OpenBSD: index.html,v 1.16 2004/05/07 01:55:23 nick Exp $ ============================================================================== PF: Getting Started ------------------------------------------------------------------------------ Table of Contents * Activation * Configuration * Control ------------------------------------------------------------------------------ Activation To activate PF and have it read its configuration file at boot add the line pf=YES to the file /etc/rc.conf.local Reboot your system to have it take effect. You can also activate and deactivate PF by using the pfctl(8) program: # pfctl -e # pfctl -d to enable and disable, respectively. Note that this just enables or disables PF, it doesn't actually load a ruleset. The ruleset must be loaded separately, either before or after PF is enabled. Configuration PF reads its configuration rules from /etc/pf.conf at boot time, as loaded by the rc scripts. Note that while /etc/pf.conf is the default and is loaded by the system rc scripts, it is just a text file loaded and interpreted by pfctl (8) and inserted into pf(4). For some applications, other rulesets may be loaded from other files after boot. As with any well designed Unix application, PF offers great flexibility. The pf.conf file has seven parts: * Macros: User-defined variables that can hold IP addresses, interface names, etc. * Tables: A structure used to hold lists of IP addresses. * Options: Various options to control how PF works. * Scrub: Reprocessing packets to normalize and defragment them. * Queueing: Provides bandwidth control and packet prioritization. * Translation: Controls Network Address Translation and packet redirection. * Filter Rules: Allows the selective filtering or blocking of packets as they pass through any of the interfaces. With the exception of macros and tables, each section should appear in this order in the configuration file, though not all sections have to exist for any particular application. Blank lines are ignored, and lines beginning with # are treated as comments. Control After boot, PF operation can be managed using the pfctl(8) program. Some example commands are: # pfctl -f /etc/pf.conf loads the pf.conf file # pfctl -nf /etc/pf.conf parse the file, but don't load it # pfctl -Nf /etc/pf.conf Load only the NAT rules from the file # pfctl -Rf /etc/pf.conf Load only the filter rules from the file # pfctl -sn Show the current NAT rules # pfctl -sr Show the current filter rules # pfctl -ss Show the current state table # pfctl -si Show filter stats and counters # pfctl -sa Show EVERYTHING it can show For a complete list of commands, please see the pfctl(8) man page. ------------------------------------------------------------------------------ $OpenBSD: config.html,v 1.13 2004/10/19 03:20:04 krw Exp $ ============================================================================== PF: Lists and Macros ------------------------------------------------------------------------------ Table of Contents * Lists * Macros ------------------------------------------------------------------------------ Lists A list allows the specification of multiple similar criteria within a rule. For example, multiple protocols, port numbers, addresses, etc. So, instead of writing one filter rule for each IP address that needs to be blocked, one rule can be written by specifying the IP addresses in a list. Lists are defined by specifying items within { } brackets. When pfctl(8) encounters a list during loading of the ruleset, it creates multiple rules, one for each item in the list. For example: block out on fxp0 from { 192.168.0.1, 10.5.32.6 } to any gets expanded to: block out on fxp0 from 192.168.0.1 to any block out on fxp0 from 10.5.32.6 to any Multiple lists can be specified within a rule and are not limited to just filter rules: rdr on fxp0 proto tcp from any to any port { 22 80 } -> \ 192.168.0.6 block out on fxp0 proto { tcp udp } from { 192.168.0.1, \ 10.5.32.6 } to any port { ssh telnet } Note that the commas between list items are optional. Macros Macros are user-defined variables that can hold IP addresses, port numbers, interface names, etc. Macros can reduce the complexity of a PF ruleset and also make maintaining a ruleset much easier. Macro names must start with a letter and may contain letters, digits, and underscores. Macro names cannot be reserved words such as pass, out, or queue. ext_if = "fxp0" block in on $ext_if from any to any This creates a macro named ext_if. When a macro is referred to after it's been created, its name is preceded with a $ character. Macros can also expand to lists, such as: friends = "{ 192.168.1.1, 10.0.2.5, 192.168.43.53 }" Macros can be defined recursively. Since macros are not expanded within quotes the following syntax must be used: host1 = "192.168.1.1" host2 = "192.168.1.2" all_hosts = "{" $host1 $host2 "}" The macro $all_hosts now expands to 192.168.1.1, 192.168.1.2. ------------------------------------------------------------------------------ $OpenBSD: macros.html,v 1.11 2004/05/07 01:55:23 nick Exp $ ============================================================================== PF: Tables ------------------------------------------------------------------------------ Table of Contents * Introduction * Configuration * Manipulating with pfctl * Specifying Addresses * Address Matching ------------------------------------------------------------------------------ Introduction A table is used to hold a group of IPv4 and/or IPv6 addresses. Lookups against a table are very fast and consume less memory and processor time than lists. For this reason, a table is ideal for holding a large group of addresses as the lookup time on a table holding 50,000 addresses is only slightly more than for one holding 50 addresses. Tables can be used in the following ways: * source and/or destination address in filter, scrub, NAT, and redirection rules. * translation address in NAT rules. * redirection address in redirection rules. * destination address in route-to, reply-to, and dup-to filter rule options. Tables are created either in pf.conf or by using pfctl(8). Configuration In pf.conf, tables are created using the table directive. The following attributes may be specified for each table: * const - the contents of the table cannot be changed once the table is created. When this attribute is not specified, pfctl(8) may be used to add or remove addresses from the table at any time, even when running with a securelevel(7) of two or greater. * persist - causes the kernel to keep the table in memory even when no rules refer to it. Without this attribute, the kernel will automatically remove the table when the last rule referencing it is flushed. Example: table { 192.0.2.0/24 } table const { 192.168.0.0/16, 172.16.0.0/12, \ 10.0.0.0/8 } table persist block in on fxp0 from { , } to any pass in on fxp0 from to any Addresses can also be specified using the negation (or "not") modifier such as: table { 192.0.2.0/24, !192.0.2.5 } The goodguys table will now match all addresses in the 192.0.2.0/24 network except for 192.0.2.5. Note that table names are always enclosed in < >. Tables can also be populated from text files containing a list of IP addresses and networks: table persist file "/etc/spammers" block in on fxp0 from to any The file /etc/spammers would contain a list of IP addresses and/or CIDR network blocks, one per line. Any line beginning with # is treated as a comment and ignored. Manipulating with pfctl Tables can be manipulated on the fly by using pfctl(8). For instance, to add entries to the table created above: # pfctl -t spammers -T add 218.70.0.0/16 This will also create the table if it doesn't already exist. To list the addresses in a table: # pfctl -t spammers -T show The -v argument can also be used with -Tshow to display statistics for each table entry. To remove addresses from a table: # pfctl -t spammers -T delete 218.70.0.0/16 For more information on manipulating tables with pfctl, please see pfctl(8). Specifying Addresses In addition to being specified by IP address, hosts may also be specified by their hostname. When the hostname is resolved to an IP address, all resulting IPv4 and IPv6 addresses are placed into the table. IP addresses can also be entered into a table by specifying a valid interface name or the self keyword. The table will then contain all IP addresses assigned to that interface or to the machine (including loopback addresses), respectively. One limitation when specifying addresses is that 0.0.0.0/0 and 0/0 will not work in tables. The alternative is to hard code that address or use a macro. Address Matching An address lookup against a table will return the most narrowly matching entry. This allows for the creation of tables such as: table { 172.16.0.0/16, !172.16.1.0/24, 172.16.1.100 } block in on dc0 all pass in on dc0 from to any Any packet coming in through dc0 will have its source address matched against the table : * 172.16.50.5 - narrowest match is 172.16.0.0/16; packet matches the table and will be passed * 172.16.1.25 - narrowest match is !172.16.1.0/24; packet matches an entry in the table but that entry is negated (uses the "!" modifier); packet does not match the table and will be blocked * 172.16.1.100 - exactly matches 172.16.1.100; packet matches the table and will be passed * 10.1.4.55 - does not match the table and will be blocked ------------------------------------------------------------------------------ $OpenBSD: tables.html,v 1.12 2004/06/03 16:08:12 nick Exp $ ============================================================================== PF: Packet Filtering ------------------------------------------------------------------------------ Table of Contents * Introduction * Rule Syntax * Default Deny * Passing Traffic * The quick Keyword * Keeping State * Keeping State for UDP * TCP Flags * TCP SYN Proxy * Blocking Spoofed Packets * Passive Operating System Fingerprinting * IP Options * Filtering Ruleset Example ------------------------------------------------------------------------------ Introduction Packet filtering is the selective passing or blocking of data packets as they pass through a network interface. The criteria that pf(4) uses when inspecting packets is based on the Layer 3 (IPv4 and IPv6) and Layer 4 (TCP, UDP, ICMP, and ICMPv6) headers. The most often used criteria are source and destination address, source and destination port, and protocol. Filter rules specify the criteria that a packet must match and the resulting action, either block or pass, that is taken when a match is found. Filter rules are evaluated in sequential order, first to last. Unless the packet matches a rule containing the quick keyword, the packet will be evaluated against all filter rules before the final action is taken. The last rule to match is the "winner" and will dictate what action to take on the packet. There is an implicit pass all at the beginning of a filtering ruleset meaning that if a packet does not match any filter rule the resulting action will be pass. Rule Syntax The general, highly simplified syntax for filter rules is: action direction [log] [quick] on interface [af] [proto protocol] \ from src_addr [port src_port] to dst_addr [port dst_port] \ [tcp_flags] [state] action The action to be taken for matching packets, either pass or block. The pass action will pass the packet back to the kernel for further processing while the block action will react based on the setting of the block-policy option. The default reaction may be overridden by specifying either block drop or block return. direction The direction the packet is moving on an interface, either in or out. log Specifies that the packet should be logged via pflogd(8). If the rule specifies the keep state, modulate state, or synproxy state option, then only the packet which establishes the state is logged. To log all packets regardless, use log-all. quick If a packet matches a rule specifying quick, then that rule is considered the last matching rule and the specified action is taken. interface The name or group of the network interface that the packet is moving through. An interface group is specified as the name of the interface but without the integer appended. For example: ppp or fxp. This would cause the rule to match for any packet traversing any ppp or fxp interface, respectively. af The address family of the packet, either inet for IPv4 or inet6 for IPv6. PF is usually able to determine this parameter based on the source and/or destination address(es). protocol The Layer 4 protocol of the packet: + tcp + udp + icmp + icmp6 + A valid protocol name from /etc/protocols + A protocol number between 0 and 255 + A set of protocols using a list. src_addr, dst_addr The source/destination address in the IP header. Addresses can be specified as: + A single IPv4 or IPv6 address. + A CIDR network block. + A fully qualified domain name that will be resolved via DNS when the ruleset is loaded. All resulting IP addresses will be substituted into the rule. + The name of a network interface. Any IP addresses assigned to the interface will be substituted into the rule. + The name of a network interface followed by /netmask (i.e., /24). Each IP address on the interface is combined with the netmask to form a CIDR network block which is substituted into the rule. + The name of a network interface in parentheses ( ). This tells PF to update the rule if the IP address(es) on the named interface change. This is useful on an interface that gets its IP address via DHCP or dial-up as the ruleset doesn't have to be reloaded each time the address changes. + The name of a network interface followed by any one of these modifiers: o :network - substitues the CIDR network block (e.g., 192.168.0.0/ 24) o :broadcast - substitutes the network broadcast address (e.g., 192.168.0.255) o :peer - substitues the peer's IP address on a point-to-point link In addition, the :0 modifier can be appended to either an interface name or to any of the above modifiers to indicate that PF should not include aliased IP addresses in the substituion. These modifiers can also be used when the interface is contained in parentheses. Example: fxp0:network:0 + A table. + Any of the above but negated using the ! ("not") modifier. + A set of addresses using a list. + The keyword any meaning all addresses + The keyword all which is short for from any to any. src_port, dst_port The source/destination port in the Layer 4 packet header. Ports can be specified as: + A number between 1 and 65535 + A valid service name from /etc/services + A set of ports using a list + A range: o != (not equal) o < (less than) o > (greater than) o <= (less than or equal) o >= (greater than or equal) o >< (range) o <> (inverse range) The last two are binary operators (they take two arguments) and do not include the arguments in the range. o : (inclusive range) The inclusive range operator is also a binary operator and does include the arguments in the range. tcp_flags Specifies the flags that must be set in the TCP header when using proto tcp. Flags are specified as flags check/mask. For example: flags S/SA - this instructs PF to only look at the S and A (SYN and ACK) flags and to match if only the SYN flag is "on". state Specifies whether state information is kept on packets matching this rule. + keep state - works with TCP, UDP, and ICMP. + modulate state - works only with TCP. PF will generate strong Initial Sequence Numbers (ISNs) for packets matching this rule. + synproxy state - proxies incoming TCP connections to help protect servers from spoofed TCP SYN floods. This option includes the functionality of keep state and modulate state. Default Deny The recommended practice when setting up a firewall is to take a "default deny" approach. That is, to deny everything and then selectively allow certain traffic through the firewall. This approach is recommended because it errs on the side of caution and also makes writing a ruleset easier. To create a default deny filter policy, the first two filter rules should be: block in all block out all This will block all traffic on all interfaces in either direction from anywhere to anywhere. Passing Traffic Traffic must now be explicitly passed through the firewall or it will be dropped by the default deny policy. This is where packet criteria such as source/destination port, source/destination address, and protocol come into play. Whenever traffic is permitted to pass through the firewall the rule(s) should be written to be as restrictive as possible. This is to ensure that the intended traffic, and only the intended traffic, is permitted to pass. Some examples: # Pass traffic in on dc0 from the local network, 192.168.0.0/24, # to the OpenBSD machine's IP address 192.168.0.1. Also, pass the # return traffic out on dc0. pass in on dc0 from 192.168.0.0/24 to 192.168.0.1 pass out on dc0 from 192.168.0.1 to 192.168.0.0/24 # Pass TCP traffic in on fxp0 to the web server running on the # OpenBSD machine. The interface name, fxp0, is used as the # destination address so that packets will only match this rule if # they're destined for the OpenBSD machine. pass in on fxp0 proto tcp from any to fxp0 port www The quick Keyword As indicated earlier, each packet is evaluated against the filter ruleset from top to bottom. By default, the packet is marked for passage, which can be changed by any rule, and could be changed back and forth several times before the end of the filter rules. The last matching rule "wins". There is an exception to this: The quick option on a filtering rule has the effect of canceling any further rule processing and causes the specified action to be taken. Let's look at a couple examples: Wrong: block in on fxp0 proto tcp from any to any port ssh pass in all In this case, the block line may be evaluated, but will never have any effect, as it is then followed by a line which will pass everything. Better: block in quick on fxp0 proto tcp from any to any port ssh pass in all These rules are evaluated a little differently. If the block line is matched, due to the quick option, the packet will be blocked, and the rest of the ruleset will be ignored. Keeping State One of Packet Filter's important abilities is "keeping state" or "stateful inspection". Stateful inspection refers to PF's ability to track the state, or progress, of a network connection. By storing information about each connection in a state table, PF is able to quickly determine if a packet passing through the firewall belongs to an already established connection. If it does, it is passed through the firewall without going through ruleset evaluation. Keeping state has many advantages including simpler rulesets and better packet filtering performance. PF is able to match packets moving in either direction to state table entries meaning that filter rules which pass returning traffic don't need to be written. And, since packets matching stateful connections don't go through ruleset evaluation, the time PF spends processing those packets can be greatly lessened. When a rule has the keep state option, the first packet matching the rule creates a "state" between the sender and receiver. Now, not only do packets going from the sender to receiver match the state entry and bypass ruleset evaluation, but so do the reply packets from receiver to sender. For example: pass out on fxp0 proto tcp from any to any keep state This allows any outbound TCP traffic on the fxp0 interface and also permits the reply traffic to pass back through the firewall. While keeping state is a nice feature, its use significantly improves the performance of your firewall as state lookups are dramatically faster than running a packet through the filter rules. The modulate state option works just like keep state except that it only applies to TCP packets. With modulate state, the Initial Sequence Number (ISN) of outgoing connections is randomized. This is useful for protecting connections initiated by certain operating systems that do a poor job of choosing ISNs. Starting with OpenBSD 3.5, the modulate state option can be used in rules that specify protocols other than TCP. Keep state on outgoing TCP, UDP, and ICMP packets and modulate TCP ISNs: pass out on fxp0 proto { tcp, udp, icmp } from any \ to any modulate state Another advantage of keeping state is that corresponding ICMP traffic will be passed through the firewall. For example, if keep state is specified for a TCP connection and an ICMP source-quench message referring to this TCP connection arrives, it will be matched to the appropriate state entry and passed through the firewall. The scope of a state entry is controlled globally by the state-policy runtime option and on a per rule basis by the if-bound, group-bound, and floating state option keywords. These per rule keywords have the same meaning as when used with the state-policy option. Example: pass out on fxp0 proto { tcp, udp, icmp } from any \ to any modulate state (if-bound) This rule would dictate that in order for packets to match the state entry, they must be transitting the fxp0 interface. Note that nat, binat, and rdr rules implicitly create state for matching connections as long as the connection is passed by the filter ruleset. Keeping State for UDP One will sometimes hear it said that, "One can not create state with UDP as UDP is a stateless protocol!" While it is true that a UDP communication session does not have any concept of state (an explicit start and stop of communications), this does not have any impact on PF's ability to create state for a UDP session. In the case of protocols without "start" and "end" packets, PF simply keeps track of how long it has been since a matching packet has gone through. If the timeout is reached, the state is cleared. The timeout values can be set in the options section of the pf.conf file. TCP Flags Matching TCP packets based on flags is most often used to filter TCP packets that are attempting to open a new connection. The TCP flags and their meanings are listed here: * F : FIN - Finish; end of session * S : SYN - Synchronize; indicates request to start session * R : RST - Reset; drop a connection * P : PUSH - Push; packet is sent immediately * A : ACK - Acknowledgement * U : URG - Urgent * E : ECE - Explicit Congestion Notification Echo * W : CWR - Congestion Window Reduced To have PF inspect the TCP flags during evaluation of a rule, the flags keyword is used with the following syntax: flags check/mask The mask part tells PF to only inspect the specified flags and the check part specifies which flag(s) must be "on" in the header for a match to occur. pass in on fxp0 proto tcp from any to any port ssh flags S/SA The above rule passes TCP traffic with the SYN flag set while only looking at the SYN and ACK flags. A packet with the SYN and ECE flags would match the above rule while a packet with SYN and ACK or just ACK would not. Note: in previous versions of OpenBSD, the following syntax was supported: . . . flags S This is no longer true. A mask must now always be specified. Flags are often used in conjunction with keep state rules to help control the creation of state entries: pass out on fxp0 proto tcp all flags S/SA keep state This would permit the creation of state on any outgoing TCP packet with the SYN flag set out of the SYN and ACK flags. One should be careful with using flags -- understand what you are doing and why, and be careful with the advice people give as a lot of it is bad. Some people have suggested creating state "only if the SYN flag is set and no others". Such a rule would end with: . . . flags S/FSRPAUEW bad idea!! The theory is, create state only on the start of the TCP session, and the session should start with a SYN flag, and no others. The problem is some sites are starting to use the ECN flag and any site using ECN that tries to connect to you would be rejected by such a rule. A much better guideline is: . . . flags S/SAFR While this is practical and safe, it is also unnecessary to check the FIN and RST flags if traffic is also being scrubbed. The scrubbing process will cause PF to drop any incoming packets with illegal TCP flag combinations (such as SYN and FIN or SYN and RST). It's highly recommended to always scrub incoming traffic: scrub in on fxp0 . . . pass in on fxp0 proto tcp from any to any port ssh flags S/SA \ keep state TCP SYN Proxy Normally when a client initiates a TCP connection to a server PF will pass the handshake packets between the two endpoints as they arrive. PF has the ability, however, to proxy the handshake. With the handshake proxied, PF itself will complete the handshake with the client, initiate a handshake with the server, and then pass packets between the two. The benefit of this process is that no packets are sent to the server before the client completes the handshake. This eliminates the threat of spoofed TCP SYN floods affecting the server because a spoofed client connection will be unable to complete the handshake. The TCP SYN proxy is enabled using the synproxy state keywords in filter rules. Example: pass in on $ext_if proto tcp from any to $web_server port www \ flags S/SA synproxy state Here, connections to the web server will be TCP proxied by PF. Because of the way synproxy state works, it also includes the same functionality as keep state and modulate state. The SYN proxy will not work if PF is running on a bridge(4). Blocking Spoofed Packets Address "spoofing" is when an malicious user fakes the source IP address in packets they transmit in order to either hide their real address or to impersonate another node on the network. Once the user has spoofed their address they can launch a network attack without revealing the true source of the attack or attempt to gain access to network services that are restricted to certain IP addresses. PF offers some protection against address spoofing through the antispoof keyword: antispoof [log] [quick] for interface [af] log Specifies that matching packets should be logged via pflogd(8). quick If a packet matches this rule then it will be considered the "winning" rule and ruleset evaluation will stop. interface The network interface to activate spoofing protection on. This can also be a list of interfaces. af The address family to activate spoofing protection for, either inet for IPv4 or inet6 for IPv6. Example: antispoof for fxp0 inet When a ruleset is loaded, any occurrences of the antispoof keyword are expanded into two filter rules. Assuming that interface fxp0 has IP address 10.0.0.1 and a subnet mask of 255.255.255.0 (i.e., a /24), the above antispoof rule would expand to: block in on ! fxp0 inet from 10.0.0.0/24 to any block in inet from 10.0.0.1 to any These rules accomplish two things: * Blocks all traffic coming from the 10.0.0.0/24 network that does not pass in through fxp0. Since the 10.0.0.0/24 network is on the fxp0 interface, packets with a source address in that network block should never be seen coming in on any other interface. * Blocks all incoming traffic from 10.0.0.1, the IP address on fxp0. The host machine should never send packets to itself through an external interface, so any incoming packets with a source address belonging to the machine can be considered malicious. NOTE: The filter rules that the antispoof rule expands to will also block packets sent over the loopback interface to local addresses. These addresses should be passed explicitly. Example: pass quick on lo0 all antispoof for fxp0 inet Usage of antispoof should be restricted to interfaces that have been assigned an IP address. Using antispoof on an interface without an IP address will result in filter rules such as: block drop in on ! fxp0 inet all block drop in inet all With these rules there is a risk of blocking all inbound traffic on all interfaces. Passive Operating System Fingerprinting Passive OS Fingerprinting (OSFP) is a method for passively detecting the operating system of a remote host based on certain characteristics within that host's TCP SYN packets. This information can then be used as criteria within filter rules. PF determines the remote operating system by comparing characteristics of a TCP SYN packet against the fingerprints file, which by default is /etc/pf.os. Once PF is enabled, the current fingerprint list can be viewed with this command: # pfctl -s osfp Within a filter rule, a fingerprint may be specified by OS class, version, or subtype/patch level. Each of these items is listed in the output of the pfctl command shown above. To specify a fingerprint in a filter rule, the os keyword is used: pass in on $ext_if any os OpenBSD keep state block in on $ext_if any os "Windows 2000" block in on $ext_if any os "Linux 2.4 ts" block in on $ext_if any os unknown The special operating system class unknown allows for matching packets when the OS fingerprint is not known. TAKE NOTE of the following: * Operating system fingerprints are occasionally wrong due to spoofed and/or crafted packets that are made to look like they originated from a specific operating system. * Certain revisions or patchlevels of an operating system may change the stack's behavior and cause it to either not match what's in the fingerprints file or to match another entry altogether. * OSFP only works on the TCP SYN packet; it will not work on other protocols or on already established connections. IP Options By default, PF blocks packets with IP options set. This can make the job more difficult for "OS fingerprinting" utilities like nmap. If you have an application that requires the passing of these packets, such as multicast or IGMP, you can use the allow-opts directive: pass in quick on fxp0 all allow-opts Filtering Ruleset Example Below is an example of a filtering ruleset. The machine running PF is acting as a firewall between a small, internal network and the Internet. Only the filter rules are shown; queueing, nat, rdr, etc., have been left out of this example. ext_if = "fxp0" int_if = "dc0" lan_net = "192.168.0.0/24" # table containing all IP addresses assigned to the firewall table const { self } # scrub incoming packets scrub in all # setup a default deny policy block in all block out all # pass traffic on the loopback interface in either direction pass quick on lo0 all # activate spoofing protection for the internal interface. antispoof quick for $int_if inet # only allow ssh connections from the local network if it's from the # trusted computer, 192.168.0.15. use "block return" so that a TCP RST is # sent to close blocked connections right away. use "quick" so that this # rule is not overridden by the "pass" rules below. block return in quick on $int_if proto tcp from ! 192.168.0.15 \ to $int_if port ssh flags S/SA # pass all traffic to and from the local network pass in on $int_if from $lan_net to any pass out on $int_if from any to $lan_net # pass tcp, udp, and icmp out on the external (Internet) interface. # keep state on udp and icmp and modulate state on tcp. pass out on $ext_if proto tcp all modulate state flags S/SA pass out on $ext_if proto { udp, icmp } all keep state # allow ssh connections in on the external interface as long as they're # NOT destined for the firewall (i.e., they're destined for a machine on # the local network). log the initial packet so that we can later tell # who is trying to connect. use the tcp syn proxy to proxy the connection. pass in log on $ext_if proto tcp from any to ! \ port ssh flags S/SA synproxy state ------------------------------------------------------------------------------ $OpenBSD: filter.html,v 1.22 2004/10/11 22:04:37 saad Exp $ ============================================================================== PF: Network Address Translation (NAT) ------------------------------------------------------------------------------ Table of Contents * Introduction * How NAT Works * NAT and Packet Filtering * IP Forwarding * Configuring NAT * Bidirectional Mapping (1:1 mapping) * Translation Rule Exceptions * Checking NAT Status ------------------------------------------------------------------------------ Introduction Network Address Translation (NAT) is a way to map an entire network (or networks) to a single IP address. NAT is necessary when the number of IP addresses assigned to you by your Internet Service Provider is less than the total number of computers that you wish to provide Internet access for. NAT is described in RFC 1631. NAT allows you to take advantage of the reserved address blocks described in RFC 1918. Typically, your internal network will be setup to use one or more of these network blocks. They are: 10.0.0.0/8 (10.0.0.0 - 10.255.255.255) 172.16.0.0/12 (172.16.0.0 - 172.31.255.255) 192.168.0.0/16 (192.168.0.0 - 192.168.255.255) An OpenBSD system doing NAT will have at least two network adapters, one to the Internet, the other to your internal network. NAT will be translating requests from the internal network so they appear to all be coming from your OpenBSD NAT system. How NAT Works When a client on the internal network contacts a machine on the Internet, it sends out IP packets destined for that machine. These packets contain all the addressing information necessary to get them to their destination. NAT is concerned with these pieces of information: * Source IP address (for example, 192.168.1.35) * Source TCP or UDP port (for example, 2132) When the packets pass through the NAT gateway they will be modified so that they appear to be coming from the NAT gateway itself. The NAT gateway will record the changes it makes in its state table so that it can a) reverse the changes on return packets and b) ensure that return packets are passed through the firewall and are not blocked. For example, the following changes might be made: * Source IP: replaced with the external address of the gateway (for example, 24.5.0.5) * Source port: replaced with a randomly chosen, unused port on the gateway (for example, 53136) Neither the internal machine nor the Internet host is aware of these translation steps. To the internal machine, the NAT system is simply an Internet gateway. To the Internet host, the packets appear to come directly from the NAT system; it is completely unaware that the internal workstation even exists. When the Internet host replies to the internal machine's packets, they will be addressed to the NAT gateway's external IP (24.5.0.5) at the translation port (53136). The NAT gateway will then search the state table to determine if the reply packets match an already established connection. A unique match will be found based on the IP/port combination which tells PF the packets belong to a connection initiated by the internal machine 192.168.1.35. PF will then make the opposite changes it made to the outgoing packets and forward the reply packets on to the internal machine. Translation of ICMP packets happens in a similar fashion but without the source port modification. NAT and Packet Filtering NOTE: Translated packets must still pass through the filter engine and will be blocked or passed based on the filter rules that have been defined. The only exception to this rule is when the pass keyword is used within the nat rule. This will cause the NATed packets to pass right through the filtering engine. Also be aware that since translation occurs before filtering, the filter engine will see the translated packet with the translated IP address and port as outlined in How NAT Works. IP Forwarding Since NAT is almost always used on routers and network gateways, it will probably be necessary to enable IP forwarding so that packets can travel between network interfaces on the OpenBSD machine. IP forwarding is enabled using the sysctl(3) mechanism: # sysctl net.inet.ip.forwarding=1 # sysctl net.inet6.ip6.forwarding=1 (if using IPv6) To make this change permanent, the following lines should be added to /etc/ sysctl.conf: net.inet.ip.forwarding=1 net.inet6.ip6.forwarding=1 These lines are present but commented out (prefixed with a #) in the default install. Remove the # and save the file. IP forwarding will be enabled when the machine is rebooted. Configuring NAT The general format for NAT rules in pf.conf looks something like this: nat [pass] on interface [af] from src_addr [port src_port] to \ dst_addr [port dst_port] -> ext_addr [pool_type] [static-port] nat The keyword that begins a NAT rule. pass Causes translated packets to completely bypass the filter rules. interface The name of the network interface to translate packets on. af The address family, either inet for IPv4 or inet6 for IPv6. PF is usually able to determine this parameter based on the source/destination address (es). src_addr The source (internal) address of packets that will be translated. The source address can be specified as: + A single IPv4 or IPv6 address. + A CIDR network block. + A fully qualified domain name that will be resolved via DNS when the ruleset is loaded. All resulting IP addresses will be substituted into the rule. + The name of a network interface. Any IP addresses assigned to the interface will be substituted into the rule at load time. + The name of a network interface followed by /netmask (e.g. /24). Each IP address on the interface is combined with the netmask to form a CIDR network block which is substituted into the rule. + The name of a network interface followed by any one of these modifiers: o :network - substitues the CIDR network block (e.g., 192.168.0.0/ 24) o :broadcast - substitutes the network broadcast address (e.g., 192.168.0.255) o :peer - substitues the peer's IP address on a point-to-point link In addition, the :0 modifier can be appended to either an interface name or to any of the above modifiers to indicate that PF should not include aliased IP addresses in the substituion. These modifiers can also be used when the interface is contained in parentheses. Example: fxp0:network:0 + A table. + Any of the above but negated using the ! ("not") modifier. + A set of addresses using a list. + The keyword any meaning all addresses src_port The source port in the Layer 4 packet header. Ports can be specified as: + A number between 1 and 65535 + A valid service name from /etc/services + A set of ports using a list + A range: o != (not equal) o < (less than) o > (greater than) o <= (less than or equal) o >= (greater than or equal) o >< (range) o <> (inverse range) The last two are binary operators (they take two arguments) and do not include the arguments in the range. o : (inclusive range) The inclusive range operator is also a binary operator and does include the arguments in the range. The port option is not usually used in nat rules because the goal is usually to NAT all traffic regardless of the port(s) being used. dst_addr The destination address of packets to be translated. The destination address is specified in the same way as the source address. dst_port The destination port in the Layer 4 packet header. This port is specified in the same way as the source port. ext_addr The external (translation) address on the NAT gateway that packets will be translated to. The external address can be specified as: + A single IPv4 or IPv6 address. + A CIDR network block. + A fully qualified domain name that will be resolved via DNS when the ruleset is loaded. + The name of the external network interface. Any IP addresses assigned to the interface will be substituted into the rule at load time. + The name of the external network interface in parentheses ( ). This tells PF to update the rule if the IP address(es) on the named interface changes. This is highly useful when the external interface gets its IP address via DHCP or dial-up as the ruleset doesn't have to be reloaded each time the address changes. + The name of a network interface followed by either one of these modifiers: o :network - substitues the CIDR network block (e.g., 192.168.0.0/ 24) o :peer - substitues the peer's IP address on a point-to-point link In addition, the :0 modifier can be appended to either an interface name or to any of the above modifiers to indicate that PF should not include aliased IP addresses in the substituion. These modifiers can also be used when the interface is contained in parentheses. Example: fxp0:network:0 + A set of addresses using a list. pool_type Specifies the type of address pool to use for translation. static-port Tells PF not to translate the source port in TCP and UDP packets. This would lead to a most basic form of this line similar to this: nat on tl0 from 192.168.1.0/24 to any -> 24.5.0.5 This rule says to perform NAT on the tl0 interface for any packets coming from 192.168.1.0/24 and to replace the source IP address with 24.5.0.5. While the above rule is correct, it is not recommended form. Maintenance could be difficult as any change of the external or internal network numbers would require the line be changed. Compare instead with this easier to maintain line (tl0 is external, dc0 internal): nat on tl0 from dc0:network to any -> tl0 The advantage should be fairly clear: you can change the IP addresses of either interface without changing this rule. When specifying an interface name for the translation address as above, the IP address is determined at pf.conf load time, not on the fly. If you are using DHCP to configure your external interface, this can be a problem. If your assigned IP address changes, NAT will continue translating outgoing packets using the old IP address. This will cause outgoing connections to stop functioning. To get around this, you can tell PF to automatically update the translation address by putting parentheses around the interface name: nat on tl0 from dc0:network to any -> (tl0) This method works for translation to both IPv4 and IPv6 addresses. Bidirectional Mapping (1:1 mapping) A bidirectional mapping can be established by using the binat rule. A binat rule establishes a one to one mapping between an internal IP address and an external address. This can be useful, for example, to provide a web server on the internal network with its own external IP address. Connections from the Internet to the external address will be translated to the internal address and connections from the web server (such as DNS requests) will be translated to the external address. TCP and UDP ports are never modified with binat rules as they are with nat rules. Example: web_serv_int = "192.168.1.100" web_serv_ext = "24.5.0.6" binat on tl0 from $web_serv_int to any -> $web_serv_ext Translation Rule Exceptions Exceptions can be made to translation rules by using the no keyword. For example, if the NAT example above was modified to look like this: no nat on tl0 from 192.168.1.10 to any nat on tl0 from 192.168.1.0/24 to any -> 24.2.74.79 Then the entire 192.168.1.0/24 network would have its packets translated to the external address 24.2.74.79 except for 192.168.1.10. Note that the first matching rule wins; if it's a no rule, then the packet is not translated. The no keyword can also be used with binat and rdr rules. Checking NAT Status To view the active NAT translations pfctl(8) is used with the -s state option. This option will list all the current NAT sessions: # pfctl -s state fxp0 TCP 192.168.1.35:2132 -> 24.5.0.5:53136 -> 65.42.33.245:22 TIME_WAIT:TIME_WAIT fxp0 UDP 192.168.1.35:2491 -> 24.5.0.5:60527 -> 24.2.68.33:53 MULTIPLE:SINGLE Explanations (first line only): fxp0 Indicates the interface that the state is bound to. The word self will appear if the state is floating. TCP The protocol being used by the connection. 192.168.1.35:2132 The IP address (192.168.1.35) of the machine on the internal network. The source port (2132) is shown after the address. This is also the address that is replaced in the IP header. 24.5.0.5:53136 The IP address (24.5.0.5) and port (53136) on the gateway that packets are being translated to. 65.42.33.245:22 The IP address (65.42.33.245) and the port (22) that the internal machine is connecting to. TIME_WAIT:TIME_WAIT This indicates what state PF believes the TCP connection to be in. ------------------------------------------------------------------------------ $OpenBSD: nat.html,v 1.16 2004/08/19 15:28:50 nick Exp $ ============================================================================== PF: Redirection (Port Forwarding) ------------------------------------------------------------------------------ Table of Contents * Introduction * Redirection and Packet Filtering * Security Implications * Redirection and Reflection + Split-Horizon DNS + Moving the Server Into a Separate Local Network + TCP Proxying + RDR and NAT Combination ------------------------------------------------------------------------------ Introduction When you have NAT running in your office you have the entire Internet available to all your machines. What if you have a machine behind the NAT gateway that needs to be accessed from outside? This is where redirection comes in. Redirection allows incoming traffic to be sent to a machine behind the NAT gateway. Let's look at an example: rdr on tl0 proto tcp from any to any port 80 -> 192.168.1.20 This line redirects TCP port 80 (web server) traffic to a machine inside the network at 192.168.1.20. So, even though 192.168.1.20 is behind your gateway and inside your network, the outside world can access it. The from any to any part of the above rdr line can be quite useful. If you know what addresses or subnets are supposed to have access to the web server at port 80, you can restrict them here: rdr on tl0 proto tcp from 27.146.49.0/24 to any port 80 -> \ 192.168.1.20 This will redirect only the specified subnet. Note this implies you can redirect different incoming hosts to different machines behind the gateway. This can be quite useful. For example, you could have users at remote sites access their own desktop computers using the same port and IP address on the gateway as long as you know the IP address they will be connecting from: rdr on tl0 proto tcp from 27.146.49.14 to any port 80 -> \ 192.168.1.20 rdr on tl0 proto tcp from 16.114.4.89 to any port 80 -> \ 192.168.1.22 rdr on tl0 proto tcp from 24.2.74.178 to any port 80 -> \ 192.168.1.23 Redirection and Packet Filtering NOTE: Translated packets must still pass through the filter engine and will be blocked or passed based on the filter rules that have been defined. The only exception to this rule is when the pass keyword is used within the rdr rule; this will cause the redirected packets to pass right through the filtering engine. Also be aware that since translation occurs before filtering, the filter engine will see the translated packet as it looks after it's had its destination IP address and/or destination port changed to match the redirection address/port specified in the rdr rule. Consider this scenario: * 192.0.2.1 - host on the Internet * 24.65.1.13 - external address of OpenBSD router * 192.168.1.5 - internal IP address of web server Redirection rule: rdr on tl0 proto tcp from 192.0.2.1 to 24.65.1.13 port 80 \ -> 192.168.1.5 port 8000 Packet before the rdr rule is processed: * Source address: 192.0.2.1 * Source port: 4028 (arbitrarily chosen by the operating system) * Destination address: 24.65.1.13 * Destination port: 80 Packet after the rdr rule is processed: * Source address: 192.0.2.1 * Source port: 4028 * Destination address: 192.168.1.5 * Destination port: 8000 The filter engine will see the IP packet as it looks after translation has taken place. Security Implications Redirection does have security implications. Punching a hole in the firewall to allow traffic into the internal, protected network potentially opens up the internal machine to compromise. If traffic is forwarded to an internal web server for example, and a vulnerability is discovered in the web server daemon or in a CGI script run on the web server, then that machine can be compromised from an intruder on the Internet. From there, the intruder has a doorway to the internal network, one that is permitted to pass right through the firewall. These risks can be minimized by keeping the externally accessed system tightly confined on a separate network. This network is often referred to as a Demilitarized Zone (DMZ) or a Private Service Network (PSN). This way, if the web server is compromised, the effects can be limited to the DMZ/PSN network by careful filtering of the traffic permitted to and from the DMZ/PSN. Redirection and Reflection Often, redirection rules are used to forward incoming connections from the Internet to a local server with a private address in the internal network or LAN, as in: server = 192.168.1.40 rdr on $ext_if proto tcp from any to $ext_if port 80 -> $server \ port 80 But when the redirection rule is tested from a client on the LAN, it doesn't work. The reason is that redirection rules apply only to packets that pass through the specified interface ($ext_if, the external interface, in the example). Connecting to the external address of the firewall from a host on the LAN, however, does not mean the packets will actually pass through its external interface. The TCP/IP stack on the firewall compares the destination address of incoming packets with its own addresses and aliases and detects connections to itself as soon as they have passed the internal interface. Such packets do not physically pass through the external interface, and the stack does not simulate such a passage in any way. Thus, PF never sees these packets on the external interface, and the redirection rule, specifying the external interface, does not apply. Adding a second redirection rule for the internal interface does not have the desired effect either. When the local client connects to the external address of the firewall, the initial packet of the TCP handshake reaches the firewall through the internal interface. The redirection rule does apply and the destination address gets replaced with that of the internal server. The packet gets forwarded back through the internal interface and reaches the internal server. But the source address has not been translated, and still contains the local client's address, so the server sends its replies directly to the client. The firewall never sees the reply and has no chance to properly reverse the translation. The client receives a reply from a source it never expected and drops it. The TCP handshake then fails and no connection can be established. Still, it's often desirable for clients on the LAN to connect to the same internal server as external clients and to do so transparently. There are several solutions for this problem: Split-Horizon DNS It's possible to configure DNS servers to answer queries from local hosts differently than external queries so that local clients will receive the internal server's address during name resolution. They will then connect directly to the local server, and the firewall isn't involved at all. This reduces local traffic since packets don't have to be sent through the firewall. Moving the Server Into a Separate Local Network Adding an additional network interface to the firewall and moving the local server from the client's network into a dedicated network (DMZ) allows redirecting of connections from local clients in the same way as the redirection of external connections. Use of separate networks has several advantages, including improving security by isolating the server from the remaining local hosts. Should the server (which in our case is reachable from the Internet) ever become compromised, it can't access other local hosts directly as all connections have to pass through the firewall. TCP Proxying A generic TCP proxy can be setup on the firewall, either listening on the port to be forwarded or getting connections on the internal interface redirected to the port it's listening on. When a local client connects to the firewall, the proxy accepts the connection, establishes a second connection to the internal server, and forwards data between those two connections. Simple proxies can be created using inetd(8) and nc(1). The following /etc/ inetd.conf entry creates a listening socket bound to the loopback address (127.0.0.1) and port 5000. Connections are forwarded to port 80 on server 192.168.1.10. 127.0.0.1:5000 stream tcp nowait nobody /usr/bin/nc nc -w \ 20 192.168.1.10 80 The following redirection rule forwards port 80 on the internal interface to the proxy: rdr on $int_if proto tcp from $int_net to $ext_if port 80 -> \ 127.0.0.1 port 5000 RDR and NAT Combination With an additional NAT rule on the internal interface, the lacking source address translation described above can be achieved. rdr on $int_if proto tcp from $int_net to $ext_if port 80 -> \ $server no nat on $int_if proto tcp from $int_if to $int_net nat on $int_if proto tcp from $int_net to $server port 80 -> \ $int_if This will cause the initial packet from the client to be translated again when it's forwarded back through the internal interface, replacing the client's source address with the firewall's internal address. The internal server will reply back to the firewall, which can reverse both NAT and RDR translations when forwarding to the local client. This construct is rather complex as it creates two separate states for each reflected connection. Care must be taken to prevent the NAT rule from applying to other traffic, for instance connections originating from external hosts (through other redirections) or the firewall itself. Note that the rdr rule above will cause the TCP/IP stack to see packets arriving on the internal interface with a destination address inside the internal network. In general, the previously mentioned solutions should be used instead. ------------------------------------------------------------------------------ $OpenBSD: rdr.html,v 1.16 2004/05/07 01:55:24 nick Exp $ ============================================================================== PF: Shortcuts For Creating Rulesets ------------------------------------------------------------------------------ Table of Contents * Introduction * Using Macros * Using Lists * PF Grammar + Elimination of Keywords + Return Simplification + Keyword Ordering ------------------------------------------------------------------------------ Introduction PF offers many ways in which a ruleset can be simplified. Some good examples are by using macros and lists. In addition, the ruleset language, or grammar, also offers some shortcuts for making a ruleset simpler. As a general rule of thumb, the simpler a ruleset is, the easier it is to understand and to maintain. Using Macros Macros are useful because they provide an alternative to hard-coding addresses, port numbers, interfaces names, etc., into a ruleset. Did a server's IP address change? No problem, just update the macro; no need to mess around with the filter rules that you've spent time and energy perfecting for your needs. A common convention in PF rulesets is to define a macro for each network interface. If a network card ever needs to be replaced with one that uses a different driver, for example swapping out a 3Com for an Intel, the macro can be updated and the filter rules will function as before. Another benefit is when installing the same ruleset on multiple machines. Certain machines may have different network cards in them, and using macros to define the network interfaces allows the rulesets to be installed with minimal editing. Using macros to define information in a ruleset that is subject to change, such as port numbers, IP addresses, and interface names, is recommended practice. # define macros for each network interface IntIF = "dc0" ExtIF = "fxp0" DmzIF = "fxp1" Another common convention is using macros to define IP addresses and network blocks. This can greatly reduce the maintenance of a ruleset when IP addresses change. # define our networks IntNet = "192.168.0.0/24" ExtAdd = "24.65.13.4" DmzNet = "10.0.0.0/24" If the internal network ever expanded or was renumbered into a different IP block, the macro can be updated: IntNet = "{ 192.168.0.0/24, 192.168.1.0/24 }" Once the ruleset is reloaded, everything will work as before. Using Lists Let's look at a good set of rules to have in your ruleset to handle RFC 1918 addresses that just shouldn't be floating around the Internet, and when they are, are usually trying to cause trouble: block in quick on tl0 inet from 127.0.0.0/8 to any block in quick on tl0 inet from 192.168.0.0/16 to any block in quick on tl0 inet from 172.16.0.0/12 to any block in quick on tl0 inet from 10.0.0.0/8 to any block out quick on tl0 inet from any to 127.0.0.0/8 block out quick on tl0 inet from any to 192.168.0.0/16 block out quick on tl0 inet from any to 172.16.0.0/12 block out quick on tl0 inet from any to 10.0.0.0/8 Now look at the following simplification: block in quick on tl0 inet from { 127.0.0.0/8, 192.168.0.0/16, \ 172.16.0.0/12, 10.0.0.0/8 } to any block out quick on tl0 inet from any to { 127.0.0.0/8, \ 192.168.0.0/16, 172.16.0.0/12, 10.0.0.0/8 } The ruleset has been reduced from eight lines down to two. Things get even better when macros are used in conjunction with a list: NoRouteIPs = "{ 127.0.0.0/8, 192.168.0.0/16, 172.16.0.0/12, \ 10.0.0.0/8 }" ExtIF = "tl0" block in quick on $ExtIF from $NoRouteIPs to any block out quick on $ExtIF from any to $NoRouteIPs Note that macros and lists simplify the pf.conf file, but the lines are actually expanded by pfctl(8) into multiple rules. So, the above example actually expands to the following rules: block in quick on tl0 inet from 127.0.0.0/8 to any block in quick on tl0 inet from 192.168.0.0/16 to any block in quick on tl0 inet from 172.16.0.0/12 to any block in quick on tl0 inet from 10.0.0.0/8 to any block out quick on tl0 inet from any to 10.0.0.0/8 block out quick on tl0 inet from any to 172.16.0.0/12 block out quick on tl0 inet from any to 192.168.0.0/16 block out quick on tl0 inet from any to 127.0.0.0/8 As you can see, the PF expansion is purely a convenience for the writer and maintainer of the pf.conf file, not an actual simplification of the rules processed by pf(4). Macros can be used to define more than just addresses and ports; they can be used anywhere in a PF rules file: pre = "pass in quick on ep0 inet proto tcp from " post = "to any port { 80, 6667 } keep state" # David's classroom $pre 21.14.24.80 $post # Nick's home $pre 24.2.74.79 $post $pre 24.2.74.178 $post Expands to: pass in quick on ep0 inet proto tcp from 21.14.24.80 to any \ port = 80 keep state pass in quick on ep0 inet proto tcp from 21.14.24.80 to any \ port = 6667 keep state pass in quick on ep0 inet proto tcp from 24.2.74.79 to any \ port = 80 keep state pass in quick on ep0 inet proto tcp from 24.2.74.79 to any \ port = 6667 keep state pass in quick on ep0 inet proto tcp from 24.2.74.178 to any \ port = 80 keep state pass in quick on ep0 inet proto tcp from 24.2.74.178 to any \ port = 6667 keep state PF Grammar Packet Filter's grammar is quite flexible which, in turn, allows for great flexibility in a ruleset. PF is able to infer certain keywords which means that they don't have to be explicitly stated in a rule, and keyword ordering is relaxed such that it isn't necessary to memorize strict syntax. Elimination of Keywords To define a "default deny" policy, two rules are used: block in all block out all This can now be reduced to: block all When no direction is specified, PF will assume the rule applies to packets moving in both directions. Similarly, the "from any to any" and "all" clauses can be left out of a rule, for example: block in on rl0 all pass in quick log on rl0 proto tcp from any to any port 22 keep state can be simplified as: block in on rl0 pass in quick log on rl0 proto tcp to port 22 keep state The first rule blocks all incoming packets from anywhere to anywhere on rl0, and the second rule passes in TCP traffic on rl0 to port 22. Return Simplification A ruleset used to block packets and reply with a TCP RST or ICMP Unreachable response could look like this: block in all block return-rst in proto tcp all block return-icmp in proto udp all block out all block return-rst out proto tcp all block return-icmp out proto udp all This can be simplified as: block return When PF sees the return keyword, it's smart enough to send the proper response, or no response at all, depending on the protocol of the packet being blocked. Keyword Ordering The order in which keywords are specified is flexible in most cases. For example, a rule written as: pass in log quick on rl0 proto tcp to port 22 \ flags S/SA keep state queue ssh label ssh Can also be written as: pass in quick log on rl0 proto tcp to port 22 \ queue ssh keep state label ssh flags S/SA Other, similar variations will also work. ------------------------------------------------------------------------------ $OpenBSD: shortcuts.html,v 1.12 2004/05/07 01:55:24 nick Exp $ ============================================================================== PF: Runtime Options ------------------------------------------------------------------------------ Options are used to control PF's operation. Options are specified in pf.conf using the set directive. set block-policy Sets the default behavior for filter rules that specify the block action. + drop - packet is silently dropped. + return - a TCP RST packet is returned for blocked TCP packets and an ICMP Unreachable packet is returned for all others. Note that individual filter rules can override the default response. set debug Set pf's debugging level. + none - no debugging messages are shown. + urgent - debug messages generated for serious errors. This is the default. + misc - debug messages generated for various errors (e.g., to see status from the packet normalizer/scrubber and for state creation failures). + loud - debug messages generated for common conditions (e.g., to see status from the passive OS fingerprinter). set fingerprints file Sets the file to load operating system fingerprints from. For use with passive OS fingerprinting. The default is /etc/pf.os. set limit frags - maximum number of entries in the memory pool used for packet reassembly (scrub rules). Default is 5000. src-nodes - maximum number of entries in the memory pool used for tracking source IP addresses (generated by the sticky-address and source-track options). Default is 10000. states - maximum number of entries in the memory pool used for state table entries (filter rules that specify keep state). Default is 10000. set loginterface int Sets the interface for which PF should gather statistics such as bytes in/ out and packets passed/blocked. Statistics can only be gathered for one interface at a time. Note that the match, bad-offset, etc., counters and the state table counters are recorded regardless of whether loginterface is set or not. set optimization Optimize PF for one of the following network environments: + normal - suitable for almost all networks. This is the default. + high-latency - high latency networks such as satellite connections. + aggressive - aggressively expires connections from the state table. This can greatly reduce the memory requirements on a busy firewall at the risk of dropping idle connections early. + conservative - extremely conservative settings. This avoids dropping idle connections at the expense of greater memory utilization and slightly increased processor utilization. set state-policy Sets PF's behavior when it comes to keeping state. This behavior can be overridden on a per rule basis. See Keeping State. + if-bound - states are bound to the interface they're created on. If traffic matches a state table entry but is not crossing the interface recorded in that state entry, the match is rejected. The packet must then match a filter rule or will be dropped/rejected altogether. + group-bound - same behavior as if-bound except packets are allowed to cross interfaces in the same group, i.e., all ppp interfaces, etc. + floating - states can match packets on any interface. As long as the packet matches a state entry it does not matter what interface it's crossing, it will pass. This is the default. set timeout interval - seconds between purges of expired states and packet fragments. frag - seconds before an unassembled fragment is expired. Example: set timeout interval 10 set timeout frag 30 set limit { frags 5000, states 2500 } set optimization high-latency set block-policy return set loginterface dc0 set fingerprints /etc/pf.os.test set state-policy if-bound ------------------------------------------------------------------------------ $OpenBSD: options.html,v 1.8 2004/05/07 01:55:23 nick Exp $ ============================================================================== PF: Scrub (Packet Normalization) ------------------------------------------------------------------------------ Table of Contents * Introduction * Options ------------------------------------------------------------------------------ Introduction "Scrubbing" is the normalization of packets so there are no ambiguities in interpretation by the ultimate destination of the packet. The scrub directive also reassembles fragmented packets, protecting some operating systems from some forms of attack, and drops TCP packets that have invalid flag combinations. A simple form of the scrub directive: scrub in all This will scrub all incoming packets on all interfaces. One reason not to scrub on an interface is if one is passing NFS through PF. Some non-OpenBSD platforms send (and expect) strange packets -- fragmented packets with the "do not fragment" bit set, which are (properly) rejected by scrub. This can be resolved by use of the no-df option. Another reason is some multi-player games have connection problems passing through PF with scrub enabled. Other than these somewhat unusual cases, scrubbing all packets is highly recommended practice. The scrub directive syntax is very similar to the filtering syntax which makes it easy to selectively scrub certain packets and not others. More on the principle and concepts of scrubbing can be found in the paper Network Intrusion Detection: Evasion, Traffic Normalization, and End-to-End Protocol Semantics. Options Scrub has the following options: no-df Clears the don't fragment bit from the IP packet header. Some operating systems are known to generate fragmented packets with the don't fragment bit set. This is particularly true with NFS. Scrub will drop such packets unless the no-df option is specified. Because some operating systems generate don't fragment packets with a zero IP identification header field, using no-df in conjunction with random-id is recommended. random-id Replaces the IP identification field of outgoing packets with random values to compensate for operating systems that use predictable values. This option only applies to outgoing packets that are not fragmented after the optional packet reassembly. min-ttl num Enforces a minimum Time To Live (TTL) in IP packet headers. max-mss num Enforces a maximum Maximum Segment Size (MSS) in TCP packet headers. fragment reassemble Buffers incoming packet fragments and reassembles them into a complete packet before passing them to the filter engine. The advantage is that filter rules only have to deal with complete packets and can ignore fragments. The drawback is the increased memory needed to buffer packet fragments. This is the default behavior when no fragment option is specified. This is also the only fragment option that works with NAT. fragment crop Causes duplicate fragments to be dropped and any overlaps to be cropped. Unlike fragment reassemble, fragments are not buffered but are passed on as soon as they arrive. fragment drop-ovl Similar to fragment crop except that all duplicate or overlapping fragments will be dropped as well as any further corresponding fragments. reassemble tcp Statefully normalizes TCP connections. When using scrub reassemble tcp, a direction (in/out) may not be specified. The following normalizations are performed: + Neither side of the connection is allowed to reduce their IP TTL. This is done to protect against an attacker sending a packet such that it reaches the firewall, affects the held state information for the connection, and expires before reaching the destination host. The TTL of all packets is raised to the highest value seen for the connection. + Modulate RFC1323 timestamps in TCP packet headers with a random number. This can prevent an observer from deducing the uptime of the host or from guessing how many hosts are behind a NAT gateway. Examples: scrub in on fxp0 all fragment reassemble min-ttl 15 max-mss 1400 scrub in on fxp0 all no-df scrub on fxp0 all reassemble tcp ------------------------------------------------------------------------------ $OpenBSD: scrub.html,v 1.9 2004/05/07 01:55:24 nick Exp $ ============================================================================== PF: Anchors and Named Rulesets ------------------------------------------------------------------------------ Table of Contents * Introduction * Named Rulesets * Anchor Options * Manipulating Named Rulesets ------------------------------------------------------------------------------ Introduction In addition to the main ruleset, PF can also evaluate sub rulesets. Since sub rulesets can be manipulated on the fly by using pfctl(8), they provide a convenient way of dynamically altering an active ruleset. Whereas a table is used to hold a dynamic list of addresses, a sub ruleset is used to hold a dynamic set of filter, nat, rdr, and binat rules. Sub rulesets are attached to the main ruleset by using anchors. There are four types of anchor rules: * anchor name - evaluates all filter rules in the anchor name * binat-anchor name - evaluates all binat rules in the anchor name * nat-anchor name - evaluates all nat rules in the anchor name * rdr-anchor name - evaluates all rdr rules in the anchor name Only the main ruleset can contain anchor rules. Named Rulesets A named ruleset is a group of filter and/or translation rules that has been assigned a name. An anchor point may contain more than one such ruleset. When PF comes across an anchor rule in the main ruleset, it will evaluate all the rulesets attached to that anchor point in alphabetical order according to their names. Processing will then continue in the main ruleset unless the packet matches a filter rule that uses the quick option or a translation rule within the anchor in which case the match will be considered final and will abort the evaluation of rules in both the anchor and the main rulesets. For example: ext_if = "fxp0" block on $ext_if all pass out on $ext_if all keep state anchor goodguys This ruleset sets a default deny policy on fxp0 for both incoming and outgoing traffic. Traffic is then statefully passed out and an anchor rule is created named goodguys. Anchors can be populated with rules by two methods: * using a load rule * using pfctl(8) The load rule causes pfctl to populate the specified anchor and named ruleset by reading rules from a text file. Example: load anchor goodguys:ssh from "/etc/anchor-goodguys-ssh" When the main ruleset is loaded, the rules listed in the file /etc/ anchor-goodguys-ssh will be loaded into the named ruleset ssh attached to the goodguys anchor. To add rules to an anchor using pfctl, the following type of command can be used: # echo "pass in proto tcp from 192.0.2.3 to any port 22" \ | pfctl -a goodguys:ssh -f - This adds a pass rule to the ruleset named ssh attached to the goodguys anchor. PF will then evaluate this rule (and any other filter rules that get added) when it reaches the anchor goodguys line in the main ruleset. Rules can also be saved and loaded from a text file: # cat >> /etc/anchor-goodguys-www pass in proto tcp from 192.0.2.3 to any port 80 pass in proto tcp from 192.0.2.4 to any port { 80 443 } # pfctl -a goodguys:www -f /etc/anchor-goodguys-www This loads the rules from the /etc/anchor-goodguys-www file into the named ruleset www in the goodguys anchor. Filter and translation rules can be loaded into a named ruleset using the same syntax and options as rules loaded into the main ruleset. One caveat, however, is that any macros that are used must also be defined within the named ruleset; macros that are defined in the main ruleset are not visible from named rulesets. Each named ruleset, as well as the main ruleset, exist separately from the other rulesets. Operations done on one ruleset, such as flushing the rules, do not affect any of the others. In addition, removing an anchor point from the main ruleset does not destroy the anchor or any named rulesets that are attached to that anchor. A named ruleset is not destroyed until it's flushed of all rules using pfctl(8). Once an anchor point has no named rulesets attached to it, it's also destroyed. Anchor Options Optionally, anchor rules can specify interface, protocol, source and destination address, tag, etc., using the same syntax as filter rules. When such information is given, anchor rules are only processed if the packet matches the anchor rule's definition. For example: ext_if = "fxp0" block on $ext_if all pass out on $ext_if all keep state anchor ssh in on $ext_if proto tcp from any to any port 22 The rules in the anchor ssh are only evaluated for TCP packets destined for port 22 that come in on fxp0. Rules are then added to the anchor like so: # echo "pass in from 192.0.2.10 to any" | pfctl -a ssh:allowed -f - So, even though the filter rule doesn't specify an interface, protocol, or port, the host 192.0.2.10 will only be permitted to connect using SSH because of the anchor rule's definition. Manipulating Named Rulesets Manipulation of named rulesets is performed via pfctl. It can be used to add and remove rules from a ruleset without reloading the main ruleset. To list all the rules in the ruleset allowed attached to the ssh anchor: # pfctl -a ssh:allowed -s rules To flush all filter rules from the same ruleset: # pfctl -a ssh:allowed -F rules If the ruleset name is omitted, the action applies to all rules in the anchor. For a full list of commands, please see pfctl(8). ------------------------------------------------------------------------------ $OpenBSD: anchors.html,v 1.12 2004/05/07 01:55:23 nick Exp $ ============================================================================== PF: Packet Queueing and Prioritization ------------------------------------------------------------------------------ Table of Contents * Queueing * Schedulers + Class Based Queueing + Priority Queueing + Random Early Detection + Explicit Congestion Notification * Configuring Queueing * Assigning Traffic to a Queue * Example #1: Small, Home Network * Example #2: Company Network ------------------------------------------------------------------------------ Queueing To queue something is to store it, in order, while it awaits processing. In a computer network, when data packets are sent out from a host, they enter a queue where they await processing by the operating system. The operating system then decides which queue and which packet(s) from that queue should be processed. The order in which the operating system selects the packets to process can affect network performance. For example, imagine a user running two network applications: SSH and FTP. Ideally, the SSH packets should be processed before the FTP packets because of the time-sensitive nature of SSH; when a key is typed in the SSH client, an immediate response is expected, but an FTP transfer being delayed by a few extra seconds hardly bears any notice. But what happens if the router handling these connections processes a large chunk of packets from the FTP connection before processing the SSH connection? Packets from the SSH connection will remain in the queue (or possibly be dropped by the router if the queue isn't big enough to hold all of the packets) and the SSH session may appear to lag or slow down. By modifying the queueing strategy being used, network bandwidth can be shared fairly between different applications, users, and computers. Note that queueing is only useful for packets in the outbound direction. Once a packet arrives on an interface in the inbound direction it's already too late to queue it -- it's already consumed network bandwidth to get to the interface that just received it. The only solution is to enable queueing on the adjacent router or, if the host that received the packet is acting as a router, to enable queueing on the internal interface where packets exit the router. Schedulers The scheduler is what decides which queues to process and in what order. By default, OpenBSD uses a First In First Out (FIFO) scheduler. A FIFO queue works like the line-up at a supermarket's checkout -- the first item into the queue is the first processed. As new packets arrive they are added to the end of the queue. If the queue becomes full, and here the analogy with the supermarket stops, newly arriving packets are dropped. This is known as tail-drop. OpenBSD supports two additional schedulers: * Class Based Queueing * Priority Queueing Class Based Queueing Class Based Queueing (CBQ) is a queueing algorithm that divides a network connection's bandwidth among multiple queues or classes. Each queue then has traffic assigned to it based on source or destination address, port number, protocol, etc. A queue may optionally be configured to borrow bandwidth from its parent queue if the parent is being under-utilized. Queues are also given a priority such that those containing interactive traffic, such as SSH, can have their packets processed ahead of queues containing bulk traffic, such as FTP. CBQ queues are arranged in an hierarchical manner. At the top of the hierarchy is the root queue which defines the total amount of bandwidth available. Child queues are created under the root queue, each of which can be assigned some portion of the root queue's bandwidth. For example, queues might be defined as follows: Root Queue (2Mbps) Queue A (1Mbps) Queue B (500Kbps) Queue C (500Kbps) In this case, the total available bandwidth is set to 2 megabits per second (Mbps). This bandwidth is then split among three child queues. The hierarchy can further be expanded by defining queues within queues. To split bandwidth equally among different users and also classify their traffic so that certain protocols don't starve others for bandwidth, a queueing structure like this might be defined: Root Queue (2Mbps) UserA (1Mbps) ssh (50Kbps) bulk (950Kbps) UserB (1Mbps) audio (250Kbps) bulk (750Kbps) http (100Kbps) other (650Kbps) Note that at each level the sum of the bandwidth assigned to each of the queues is not more than the bandwidth assigned to the parent queue. A queue can be configured to borrow bandwidth from its parent if the parent has excess bandwidth available due to it not being used by the other child queues. Consider a queueing setup like this: Root Queue (2Mbps) UserA (1Mbps) ssh (100Kbps) ftp (900Kbps, borrow) UserB (1Mbps) If traffic in the ftp queue exceeds 900Kbps and traffic in the UserA queue is less than 1Mbps (because the ssh queue is using less than its assigned 100Kbps), the ftp queue will borrow the excess bandwidth from UserA. In this way the ftp queue is able to use more than its assigned bandwidth when it faces overload. When the ssh queue increases its load, the borrowed bandwidth will be returned. CBQ assigns each queue a priority level. Queues with a higher priority are preferred during congestion over queues with a lower priority as long as both queues share the same parent (in other words, as long as both queues are on the same branch in the hierarchy). Queues with the same priority are processed in a round-robin fashion. For example: Root Queue (2Mbps) UserA (1Mbps, priority 1) ssh (100Kbps, priority 5) ftp (900Kbps, priority 3) UserB (1Mbps, priority 1) CBQ will process the UserA and UserB queues in a round-robin fashion -- neither queue will be preferred over the other. During the time when the UserA queue is being processed, CBQ will also process its child queues. In this case, the ssh queue has a higher priority and will be given preferential treatment over the ftp queue if the network is congested. Note how the ssh and ftp queues do not have their priorities compared to the UserA and UserB queues because they are not all on the same branch in the hierarchy. For a more detailed look at the theory behind CBQ, please see References on CBQ. Priority Queueing Priority Queueing (PRIQ) assigns multiple queues to a network interface with each queue being given a unique priority level. A queue with a higher priority is always processed ahead of a queue with a lower priority. The queueing structure in PRIQ is flat -- you cannot define queues within queues. The root queue is defined, which sets the total amount of bandwidth that is available, and then sub queues are defined under the root. Consider the following example: Root Queue (2Mbps) Queue A (priority 1) Queue B (priority 2) Queue C (priority 3) The root queue is defined as having 2Mbps of bandwidth available to it and three subqueues are defined. The queue with the highest priority (the highest priority number) is served first. Once all the packets in that queue are processed, or if the queue is found to be empty, PRIQ moves onto the queue with the next highest priority. Within a given queue, packets are processed in a First In First Out (FIFO) manner. It is important to note that when using PRIQ you must plan your queues very carefully. Because PRIQ always processes a higher priority queue before a lower priority one, it's possible for a high priority queue to cause packets in a lower priority queue to be delayed or dropped if the high priority queue is receiving a constant stream of packets. Random Early Detection Random Early Detection (RED) is a congestion avoidance algorithm. Its job is to avoid network congestion by making sure that the queue doesn't become full. It does this by continually calculating the average length (size) of the queue and comparing it to two thresholds, a minimum threshold and a maximum threshold. If the average queue size is below the minimum threshold then no packets will be dropped. If the average is above the maximum threshold then all newly arriving packets will be dropped. If the average is between the threshold values then packets are dropped based on a probability calculated from the average queue size. In other words, as the average queue size approaches the maximum threshold, more and more packets are dropped. When dropping packets, RED randomly chooses which connections to drop packets from. Connections using larger amounts of bandwidth have a higher probability of having their packets dropped. RED is useful because it avoids a situation known as global synchronization and it is able to accommodate bursts of traffic. Global synchronization refers to a loss of total throughput due to packets being dropped from several connections at the same time. For example, if congestion occurs at a router carrying traffic for 10 FTP connections and packets from all (or most) of these connections are dropped (as is the case with FIFO queueing), overall throughput will drop sharply. This isn't an ideal situation because it causes all of the FTP connections to reduce their throughput and also means that the network is no longer being used to its maximum potential. RED avoids this by randomly choosing which connections to drop packets from instead of choosing all of them. Connections using large amounts of bandwidth have a higher chance of their packets being dropped. In this way, high bandwidth connections will be throttled back, congestion will be avoided, and sharp losses of overall throughput will not occur. In addition, RED is able to handle bursts of traffic because it starts to drop packets before the queue becomes full. When a burst of traffic comes through there will be enough space in the queue to hold the new packets. RED should only be used when the transport protocol is capable of responding to congestion indicators from the network. In most cases this means RED should be used to queue TCP traffic and not UDP or ICMP traffic. For a more detailed look at the theory behind RED, please see References on RED. Explicit Congestion Notification Explicit Congestion Notification (ECN) works in conjunction with RED to notify two hosts communicating over the network of any congestion along the communication path. It does this by enabling RED to set a flag in the packet header instead of dropping the packet. Assuming the sending host has support for ECN, it can then read this flag and throttle back its network traffic accordingly. For more information on ECN, please refer to RFC 3168. Configuring Queueing Since OpenBSD 3.0 the Alternate Queueing (ALTQ) queueing implementation has been a part of the base system. Starting with OpenBSD 3.3 ALTQ has been integrated into PF. OpenBSD's ALTQ implementation supports the Class Based Queueing (CBQ) and Priority Queueing (PRIQ) schedulers. It also supports Random Early Detection (RED) and Explicit Congestion Notification (ECN). Because ALTQ has been merged with PF, PF must be enabled for queueing to work. Instructions on how to enable PF can be found in Getting Started. Queueing is configured in pf.conf. There are two types of directives that are used to configure queueing: * altq on - enables queueing on an interface, defines which scheduler to use, and creates the root queue * queue - defines the properties of a child queue The syntax for the altq on directive is: altq on interface scheduler bandwidth bw qlimit qlim \ tbrsize size queue { queue_list } * interface - the network interface to activate queueing on. * scheduler - the queueing scheduler to use. Possible values are cbq and priq. Only one scheduler may be active on an interface at a time. * bw - the total amount of bandwidth available to the scheduler. This may be specified as an absolute value using the suffixes b, Kb, Mb, and Gb to represent bits, kilobits, megabits, and gigabits per second, respectively or as a percentage of the interface bandwidth. * qlim - the maximum number of packets to hold in the queue. This parameter is optional. The default is 50. * size - the size of the token bucket regulator in bytes. If not specified, the size is set based on the interface bandwidth. * queue_list - a list of child queues to create under the root queue. For example: altq on fxp0 cbq bandwidth 2Mb queue { std, ssh, ftp } This enables CBQ on the fxp0 interface. The total bandwidth available is set to 2Mbps. Three child queues are defined: std, ssh, and ftp. The syntax for the queue directive is: queue name [on interface] bandwidth bw [priority pri] [qlimit qlim] \ scheduler ( sched_options ) { queue_list } * name - the name of the queue. This must match the name of one of the queues defined in the altq on directive's queue_list. For cbq it can also match the name of a queue in a previous queue directive's queue_list. Queue names must be no longer than 15 characters. * interface - the network interface that the queue is valid on. This value is optional, and when not specified, will make the queue valid on all interfaces. * bw - the total amount of bandwidth available to the queue. This may be specified as an absolute value using the suffixes b, Kb, Mb, and Gb to represent bits, kilobits, megabits, and gigabits per second, respectively or as a percentage of the parent queue's bandwidth. This parameter is only applicable when using the cbq scheduler. * pri - the priority of the queue. For cbq the priority range is 0 to 7 and for priq the range is 0 to 15. Priority 0 is the lowest priority. When not specified, a default of 1 is used. * qlim - the maximum number of packets to hold in the queue. When not specified, a default of 50 is used. * scheduler - the scheduler being used, either cbq or priq. Must be the same as the root queue. * sched_options - further options may be passed to the scheduler to control its behavior: + default - defines a default queue where all packets not matching any other queue will be queued. Exactly one default queue is required. + red - enables Random Early Detection (RED) on this queue. + rio - enables RED with IN/OUT. In this mode, RED will maintain multiple average queue lengths and multiple threshold values, one for each IP Quality of Service level. + ecn - enables Explicit Congestion Notification (ECN) on this queue. Ecn implies red. + borrow - the queue can borrow bandwidth from its parent. This can only be specified when using the cbq scheduler. * queue_list - a list of child queues to create under this queue. A queue_list may only be defined when using the cbq scheduler. Continuing with the example above: queue std bandwidth 50% cbq(default) queue ssh { ssh_login, ssh_bulk } queue ssh_login priority 4 cbq(ecn) queue ssh_bulk cbq(ecn) queue ftp bandwidth 500Kb priority 3 cbq(borrow red) Here the parameters of the previously defined child queues are set. The std queue is assigned a bandwidth of 50% of the root queue's bandwidth (or 1Mbps) and is set as the default queue. The ssh queue defines two child queues, ssh_login and ssh_bulk. The ssh_login queue is given a higher priority than ssh_bulk and both have ECN enabled. The ftp queue is assigned a bandwidth of 500Kbps and given a priority of 3. It can also borrow bandwidth when extra is available and has RED enabled. Assigning Traffic to a Queue To assign traffic to a queue, the queue keyword is used in conjunction with PF's filter rules. For example, consider a set of filtering rules containing a line such as: pass out on fxp0 from any to any port 22 Packets matching that rule can be assigned to a specific queue by using the queue keyword: pass out on fxp0 from any to any port 22 queue ssh When using the queue keyword with block directives, any resulting TCP RST or ICMP Unreachable packets are assigned to the specified queue. Note that queue designation can happen on an interface other than the one defined in the altq on directive: altq on fxp0 cbq bandwidth 2Mb queue { std, ftp } queue std cbq(default) queue ftp bandwidth 1.5Mb pass in on dc0 from any to any port 21 queue ftp Queueing is enabled on fxp0 but the designation takes place on dc0. If packets matching the pass rule exit from interface fxp0, they will be queued in the ftp queue. This type of queueing can be very useful on routers. Normally only one queue name is given with the queue keyword, but if a second name is specified that queue will be used for packets with a Type of Service (ToS) of low-delay and for TCP ACK packets with no data payload. A good example of this is found when using SSH. SSH login sessions will set the ToS to low-delay while SCP and SFTP sessions will not. PF can use this information to queue packets belonging to a login connection in a different queue than non-login connections. This can be useful to prioritize login connection packets over file transfer packets. pass out on fxp0 from any to any port 22 queue(ssh_bulk, ssh_login) This assigns packets belonging to SSH login connections to the ssh_login queue and packets belonging to SCP and SFTP connections to the ssh_bulk queue. SSH login connections will then have their packets processed ahead of SCP and SFTP connections because the ssh_login queue has a higher priority. Assigning TCP ACK packets to a higher priority queue is useful on asymmetric connections, that is, connections that have different upload and download bandwidths such as ADSL lines. With an ADSL line, if the upload channel is being maxed out and a download is started, the download will suffer because the TCP ACK packets it needs to send will run into congestion when they try to pass through the upload channel. Testing has shown that to achieve the best results, the bandwidth on the upload queue should be set to a value less than what the connection is capable of. For instance, if an ADSL line has a max upload of 640Kbps, setting the root queue's bandwidth to a value such as 600Kb should result in better performance. Trial and error will yield the best bandwidth setting. When using the queue keyword with rules that keep state such as: pass in on fxp0 proto tcp from any to any port 22 flags S/SA \ keep state queue ssh PF will record the queue in the state table entry so that packets traveling back out fxp0 that match the stateful connection will end up in the ssh queue. Note that even though the queue keyword is being used on a rule filtering incoming traffic, the goal is to specify a queue for the corresponding outgoing traffic; the above rule does not queue incoming packets. Example #1: Small, Home Network [ Alice ] [ Charlie ] | | ADSL ---+-----+-------+------ dc0 [ OpenBSD ] fxp0 -------- ( Internet ) | [ Bob ] In this example, OpenBSD is being used on an Internet gateway for a small home network with three workstations. The gateway is performing packet filtering and NAT duties. The Internet connection is via an ADSL line running at 2Mbps down and 640Kbps up. The queueing policy for this network: * Reserve 80Kbps of download bandwidth for Bob so he can play his online games without being lagged by Alice or Charlie's downloads. Allow Bob to use more than 80Kbps when it's available. * Interactive SSH and instant message traffic will have a higher priority than regular traffic. * DNS queries and replies will have the second highest priority. * Outgoing TCP ACK packets will have a higher priority than all other outgoing traffic. Below is the ruleset that meets this network policy. Note that only the pf.conf directives that apply directly to the above policy are present; nat, rdr, options, etc., are not shown. # enable queueing on the external interface to control traffic going to # the Internet. use the priq scheduler to control only priorities. set # the bandwidth to 610Kbps to get the best performance out of the TCP # ACK queue. altq on fxp0 priq bandwidth 610Kb queue { std_out, ssh_im_out, dns_out, \ tcp_ack_out } # define the parameters for the child queues. # std_out - the standard queue. any filter rule below that does not # explicitly specify a queue will have its traffic added # to this queue. # ssh_im_out - interactive SSH and various instant message traffic. # dns_out - DNS queries. # tcp_ack_out - TCP ACK packets with no data payload. queue std_out priq(default) queue ssh_im_out priority 4 priq(red) queue dns_out priority 5 queue tcp_ack_out priority 6 # enable queueing on the internal interface to control traffic coming in # from the Internet. use the cbq scheduler to control bandwidth. max # bandwidth is 2Mbps. altq on dc0 cbq bandwidth 2Mb queue { std_in, ssh_im_in, dns_in, bob_in } # define the parameters for the child queues. # std_in - the standard queue. any filter rule below that does not # explicitly specify a queue will have its traffic added # to this queue. # ssh_im_in - interactive SSH and various instant message traffic. # dns_in - DNS replies. # bob_in - bandwidth reserved for Bob's workstation. allow him to # borrow. queue std_in cbq(default) queue ssh_im_in priority 4 queue dns_in priority 5 queue bob_in bandwidth 80Kb cbq(borrow) # ... in the filtering section of pf.conf ... alice = "192.168.0.2" bob = "192.168.0.3" charlie = "192.168.0.4" local_net = "192.168.0.0/24" ssh_ports = "{ 22 2022 }" im_ports = "{ 1863 5190 5222 }" # filter rules for fxp0 inbound block in on fxp0 all # filter rules for fxp0 outbound block out on fxp0 all pass out on fxp0 inet proto tcp from (fxp0) to any flags S/SA \ keep state queue(std_out, tcp_ack_out) pass out on fxp0 inet proto { udp icmp } from (fxp0) to any keep state pass out on fxp0 inet proto { tcp udp } from (fxp0) to any port domain \ keep state queue dns_out pass out on fxp0 inet proto tcp from (fxp0) to any port $ssh_ports \ flags S/SA keep state queue(std_out, ssh_im_out) pass out on fxp0 inet proto tcp from (fxp0) to any port $im_ports \ flags S/SA keep state queue(ssh_im_out, tcp_ack_out) # filter rules for dc0 inbound block in on dc0 all pass in on dc0 from $local_net # filter rules for dc0 outbound block out on dc0 all pass out on dc0 from any to $local_net pass out on dc0 proto { tcp udp } from any port domain to $local_net \ queue dns_in pass out on dc0 proto tcp from any port $ssh_ports to $local_net \ queue(std_in, ssh_im_in) pass out on dc0 proto tcp from any port $im_ports to $local_net \ queue ssh_im_in pass out on dc0 from any to $bob queue bob_in Example #2: Company Network ( IT Dept ) [ Boss's PC ] | | T1 --+----+-----+---------- dc0 [ OpenBSD ] fxp0 -------- ( Internet ) | fxp1 [ COMP1 ] [ WWW ] / | / --+----------' In this example, the OpenBSD host is acting as a firewall for a company network. The company runs a WWW server in the DMZ portion of their network where customers upload their websites via FTP. The IT department has their own subnet connected to the main network, and the boss has a PC on his desk that's used for email and surfing the web. The connection to the Internet is via a T1 line running at 1.5Mbps in both directions. All other network segments are using Fast Ethernet (100Mbps). The network administrator has decided on the following policy: * Limit traffic between the WWW server and the Internet to 500Kbps in each direction. * No bandwidth limit on traffic between the WWW server and the internal network. * Give HTTP traffic between the WWW server and the Internet a higher priority than other traffic between the WWW server and the Internet (such as FTP uploads). * Reserve 500Kbps for the IT Dept network so they can download the latest software updates in a timely manner. They should be able to use more than 500Kbps when extra bandwidth is available. * Give traffic between the boss's PC and the Internet a higher priority than other traffic to/from the Internet. Below is the ruleset that meets this network policy. Note that only the pf.conf directives that apply directly to the above policy are present; nat, rdr, options, etc., are not shown. # enable queueing on the external interface to queue packets going out # to the Internet. use the cbq scheduler so that the bandwidth use of # each queue can be controlled. the max outgoing bandwidth is 1.5Mbps. altq on fxp0 cbq bandwidth 1.5Mb queue { std_ext, www_ext, boss_ext } # define the parameters for the child queues. # std_ext - the standard queue. also the default queue for # outgoing traffic on fxp0. # www_ext - container queue for WWW server queues. limit to # 500Kbps. # www_ext_http - http traffic from the WWW server # www_ext_misc - all non-http traffic from the WWW server # boss_ext - traffic coming from the boss's computer queue std_ext cbq(default) queue www_ext bandwidth 500Kb { www_ext_http, www_ext_misc } queue www_ext_http priority 3 cbq(red) queue www_ext_misc priority 1 queue boss_ext priority 3 # enable queueing on the internal interface to control traffic coming # from the Internet or the DMZ. use the cbq scheduler to control the # bandwidth of each queue. bandwidth on this interface is set to the # maximum. traffic coming from the DMZ will be able to use all of this # bandwidth while traffic coming from the Internet will be limited to # 1.0Mbps (because 0.5Mbps (500Kbps) is being allocated to fxp1). altq on dc0 cbq bandwidth 100% queue { net_int, www_int } # define the parameters for the child queues. # net_int - container queue for traffic from the Internet. bandwidth # is 1.0Mbps. # std_int - the standard queue. also the default queue for outgoing # traffic on dc0. # it_int - traffic to the IT Dept network. # boss_int - traffic to the boss's PC. # www_int - traffic from the WWW server in the DMZ. queue net_int bandwidth 1.0Mb { std_int, it_int, boss_int } queue std_int cbq(default) queue it_int bandwidth 500Kb cbq(borrow) queue boss_int priority 3 queue www_int cbq(red) # enable queueing on the DMZ interface to control traffic destined for # the WWW server. cbq will be used on this interface since detailed # control of bandwidth is necessary. bandwidth on this interface is set # to the maximum. traffic from the internal network will be able to use # all of this bandwidth while traffic from the Internet will be limited # to 500Kbps. altq on fxp1 cbq bandwidth 100% queue { internal_dmz, net_dmz } # define the parameters for the child queues. # internal_dmz - traffic from the internal network. # net_dmz - container queue for traffic from the Internet. # net_dmz_http - http traffic. # net_dmz_misc - all non-http traffic. this is also the default queue. queue internal_dmz # no special settings needed queue net_dmz bandwidth 500Kb { net_dmz_http, net_dmz_misc } queue net_dmz_http priority 3 cbq(red) queue net_dmz_misc priority 1 cbq(default) # ... in the filtering section of pf.conf ... main_net = "192.168.0.0/24" it_net = "192.168.1.0/24" int_nets = "{ 192.168.0.0/24, 192.168.1.0/24 }" dmz_net = "10.0.0.0/24" boss = "192.168.0.200" wwwserv = "10.0.0.100" # default deny block on { fxp0, fxp1, dc0 } all # filter rules for fxp0 inbound pass in on fxp0 proto tcp from any to $wwwserv port { 21, \ > 49151 } flags S/SA keep state queue www_ext_misc pass in on fxp0 proto tcp from any to $wwwserv port 80 \ flags S/SA keep state queue www_ext_http # filter rules for fxp0 outbound pass out on fxp0 from $int_nets to any keep state pass out on fxp0 from $boss to any keep state queue boss_ext # filter rules for dc0 inbound pass in on dc0 from $int_nets to any keep state pass in on dc0 from $it_net to any queue it_int pass in on dc0 from $boss to any queue boss_int pass in on dc0 proto tcp from $int_nets to $wwwserv port { 21, 80, \ > 49151 } flags S/SA keep state queue www_int # filter rules for dc0 outbound pass out on dc0 from dc0 to $int_nets # filter rules for fxp1 inbound pass in on fxp1 proto { tcp, udp } from $wwwserv to any port 53 \ keep state # filter rules for fxp1 outbound pass out on fxp1 proto tcp from any to $wwwserv port { 21, \ > 49151 } flags S/SA keep state queue net_dmz_misc pass out on fxp1 proto tcp from any to $wwwserv port 80 \ flags S/SA keep state queue net_dmz_http pass out on fxp1 proto tcp from $int_nets to $wwwserv port { 80, \ 21, > 49151 } flags S/SA keep state queue internal_dmz ------------------------------------------------------------------------------ $OpenBSD: queueing.html,v 1.22 2004/06/21 17:48:32 saad Exp $ ============================================================================== PF: Address Pools and Load Balancing ------------------------------------------------------------------------------ Table of Contents * Introduction * NAT Address Pool * Load Balancing Incoming Connections * Load Balancing Outgoing Traffic + Ruleset Example ------------------------------------------------------------------------------ Introduction An address pool is a supply of two or more addresses whose use is shared among a group of users. An address pool can be specified as the redirection address in rdr rules, as the translation address in nat rules, and as the target address in route-to, reply-to, and dup-to filter options. There are four methods for using an address pool: * bitmask - grafts the network portion of the pool address over top of the address that is being modified (source address for nat rules, destination address for rdr rules). Example: if the address pool is 192.0.2.1/24 and the address being modified is 10.0.0.50, then the resulting address will be 192.0.2.50. If the address pool is 192.0.2.1/25 and the address being modified is 10.0.0.130, then the resulting address will be 192.0.2.2. * random - randomly selects an address from the pool. * source-hash - uses a hash of the source address to determine which address to use from the pool. This method ensures that a given source address is always mapped to the same pool address. The key that is fed to the hashing algorithm can optionally be specified after the source-hash keyword in hex format or as a string. By default, pfctl(8) will generate a random key every time the ruleset is loaded. * round-robin - loops through the address pool in sequence. This is the default method and also the only method allowed when the address pool is specified using a table. Except for the round-robin method, the address pool must be expressed as a CIDR (Classless Inter-Domain Routing) network block. The round-robin method will accept multiple individual addresses using a list or table. The sticky-address option can be used with the random and round-robin pool types to ensure that a particular source address is always mapped to the same redirection address. NAT Address Pool An address pool can be used as the translation address in nat rules. Connections will have their source address translated to an address from the pool based on the method chosen. This can be useful in situations where PF is performing NAT for a very large network. Since the number of NATed connections per translation address is limited, adding additional translation addresses will allow the NAT gateway to scale to serve a larger number of users. In this example a pool of two addresses is being used to translate outgoing packets. For each outgoing connection PF will rotate through the addresses in a round-robin manner. nat on $ext_if inet from any to any -> { 192.0.2.5, 192.0.2.10 } One drawback with this method is that successive connections from the same internal address will not always be translated to the same translation address. This can cause interference, for example, when browsing websites that track user logins based on IP address. An alternate approach is to use the source-hash method so that each internal address is always translated to the same translation address. To do this, the address pool must be a CIDR network block. nat on $ext_if inet from any to any -> 192.0.2.4/31 source-hash This nat rule uses the address pool 192.0.2.4/31 (192.0.2.4 - 192.0.2.5) as the translation address for outgoing packets. Each internal address will always be translated to the same translation address because of the source-hash keyword. Load Balance Incoming Connections Address pools can also be used to load balance incoming connections. For example, incoming web server connections can be distributed across a web server farm: web_servers = "{ 10.0.0.10, 10.0.0.11, 10.0.0.13 }" rdr on $ext_if proto tcp from any to any port 80 -> $web_servers \ round-robin sticky-address Successive connections will be redirected to the web servers in a round-robin manner with connections from the same source being sent to the same web server. This "sticky connection" will exist as long as there are states that refer to this connection. Once the states expire, so will the sticky connection. Further connections from that host will be redirected to the next web server in the round robin. Load Balance Outgoing Traffic Address pools can be used in combination with the route-to filter option to load balance two or more Internet connections when a proper multi-path routing protocol (like BGP4) is unavailable. By using route-to with a round-robin address pool, outbound connections can be evenly distributed among multiple outbound paths. One additional piece of information that's needed to do this is the IP address of the adjacent router on each Internet connection. This is fed to the route-to option to control the destination of outgoing packets. The following example balances outgoing traffic across two Internet connections: lan_net = "192.168.0.0/24" int_if = "dc0" ext_if1 = "fxp0" ext_if2 = "fxp1" ext_gw1 = "68.146.224.1" ext_gw2 = "142.59.76.1" pass in on $int_if route-to \ { ($ext_if1 $ext_gw1), ($ext_if2 $ext_gw2) } round-robin \ from $lan_net to any keep state The route-to option is used on traffic coming in on the internal interface to specify the outgoing network interfaces that traffic will be balanced across along with their respective gateways. Note that the route-to option must be present on each filter rule that traffic is to be balanced for. Return packets will be routed back to the same external interface that they exited (this is done by the ISPs) and will be routed back to the internal network normally. To ensure that packets with a source address belonging to $ext_if1 are always routed to $ext_gw1 (and similarly for $ext_if2 and $ext_gw2), the following two lines should be included in the ruleset: pass out on $ext_if1 route-to ($ext_if2 $ext_gw2) from $ext_if2 \ to any pass out on $ext_if2 route-to ($ext_if1 $ext_gw1) from $ext_if1 \ to any Finally, NAT can also be used on each outgoing interface: nat on $ext_if1 from $lan_net to any -> ($ext_if1) nat on $ext_if2 from $lan_net to any -> ($ext_if2) A complete example that load balances outgoing traffic might look something like this: lan_net = "192.168.0.0/24" int_if = "dc0" ext_if1 = "fxp0" ext_if2 = "fxp1" ext_gw1 = "68.146.224.1" ext_gw2 = "142.59.76.1" # nat outgoing connections on each internet interface nat on $ext_if1 from $lan_net to any -> ($ext_if1) nat on $ext_if2 from $lan_net to any -> ($ext_if2) # default deny block in from any to any block out from any to any # pass all outgoing packets on internal interface pass out on $int_if from any to $lan_net # pass in quick any packets destined for the gateway itself pass in quick on $int_if from $lan_net to $int_if # load balance outgoing tcp traffic from internal network. pass in on $int_if route-to \ { ($ext_if1 $ext_gw1), ($ext_if2 $ext_gw2) } round-robin \ proto tcp from $lan_net to any flags S/SA modulate state # load balance outgoing udp and icmp traffic from internal network pass in on $int_if route-to \ { ($ext_if1 $ext_gw1), ($ext_if2 $ext_gw2) } round-robin \ proto { udp, icmp } from $lan_net to any keep state # general "pass out" rules for external interfaces pass out on $ext_if1 proto tcp from any to any flags S/SA modulate state pass out on $ext_if1 proto { udp, icmp } from any to any keep state pass out on $ext_if2 proto tcp from any to any flags S/SA modulate state pass out on $ext_if2 proto { udp, icmp } from any to any keep state # route packets from any IPs on $ext_if1 to $ext_gw1 and the same for # $ext_if2 and $ext_gw2 pass out on $ext_if1 route-to ($ext_if2 $ext_gw2) from $ext_if2 to any pass out on $ext_if2 route-to ($ext_if1 $ext_gw1) from $ext_if1 to any ------------------------------------------------------------------------------ $OpenBSD: pools.html,v 1.12 2004/05/07 01:55:24 nick Exp $ ============================================================================== PF: Packet Tagging ------------------------------------------------------------------------------ Table of Contents * Introduction * Assigning Tags to Packets * Checking for Applied Tags * Policy Filtering * Tagging Ethernet Frames ------------------------------------------------------------------------------ Introduction Packet tagging is a way of marking packets with an internal identifier that can later be used in filter and translation rule criteria. With tagging, it's possible to do such things as create "trusts" between interfaces and determine if packets have been processed by translation rules. It's also possible to move away from rule-based filtering and to start doing policy-based filtering. Assigning Tags to Packets To add a tag to a packet, use the tag keyword: pass in on $int_if all tag INTERNAL_NET keep state The tag INTERNAL_NET will be added to any packet which matches the above rule. Note the use of keep state; keep state (or modulate state/synproxy state) must be used in pass rules that tag packets. A tag can also be assigned using a macro. For instance: name = "INTERNAL_NET" pass in on $int_if all tag $name keep state There are a set of predefined macros which can also be used. * $if - The interface * $srcaddr - Source IP address * $dstaddr - Destination IP address * $srcport - The source port specification * $dstport - The destination port specification * $proto - The protocol * $nr - The rule number These macros are expanded at ruleset load time and NOT at runtime. Tagging follows these rules: * Tags are "sticky". Once a tag is applied to a packet by a matching rule it is never removed. It can, however, be replaced with a different tag. * Because of a tag's "stickiness", a packet can have a tag even if the last matching rule doesn't use the tag keyword. * A packet is only ever assigned a maximum of one tag at a time. * Tags are internal identifiers. Tags are not sent out over the wire. Take the following ruleset as an example. (1) pass in on $int_if tag INT_NET keep state (2) pass in quick on $int_if proto tcp to port 80 tag \ INT_NET_HTTP keep state (3) pass in quick on $int_if from 192.168.1.5 keep state * Packets coming in on $int_if will be assigned a tag of INT_NET by rule #1. * TCP packets coming in on $int_if and destined for port 80 will first be assigned a tag of INT_NET by rule #1. That tag will then be replaced with the INT_NET_HTTP tag by rule #2. * Packets coming in on $int_if from 192.168.1.5 will be passed by rule #3 since it's the last matching rule. However, those packets will be tagged with the INT_NET_HTTP tag if they were destined for TCP port 80, otherwise they'll be tagged with the INT_NET tag. In addition to applying tags with filter rules, the nat, rdr, and binat translation rules can also apply tags to packets by using the tag keyword. Checking for Applied Tags To check for previously applied tags, use the tagged keyword: pass out on $ext_if tagged INT_NET keep state Outgoing packets on $ext_if must be tagged with the INT_NET tag in order to match the above rule. Inverse matching can also be done by using the ! operator: pass out on $ext_if tagged ! WIFI_NET keep state Policy Filtering Policy filtering takes a different approach to writing a filter ruleset. A policy is defined which sets the rules for what types of traffic is passed and what types are blocked. Packets are then classified into the policy based on the traditional criteria of source/destination IP address/port, protocol, etc. For example, examine the following firewall policy: * Traffic from the internal LAN to the DMZ is permitted (LAN_DMZ) * Traffic from the Internet to servers in the DMZ is permitted (INET_DMZ) * Traffic from the Internet that's being redirected to spamd(8) is permitted (SPAMD) * All other traffic is blocked Note how the policy covers all traffic that will be passing through the firewall. The item in parenthesis indicates the tag that will be used for that policy item. Filter and translation rules now need to be written to classify packets into the policy. rdr on $ext_if proto tcp from to port smtp \ tag SPAMD -> 127.0.0.1 port 8025 block all pass in on $int_if from $int_net tag LAN_INET keep state pass in on $int_if from $int_net to $dmz_net tag LAN_DMZ keep state pass in on $ext_if proto tcp to $www_server port 80 tag INET_DMZ keep state Now the rules that define the policy are set. pass in quick on $ext_if tagged SPAMD keep state pass out quick on $ext_if tagged LAN_INET keep state pass out quick on $dmz_if tagged LAN_DMZ keep state pass out quick on $dmz_if tagged INET_DMZ keep state Now that the whole ruleset is setup, changes are a matter of modifying the classification rules. For example, if a POP3/SMTP server is added to the DMZ, it will be necessary to add classification rules for POP3 and SMTP traffic, like so: mail_server = "192.168.0.10" ... pass in on $ext_if proto tcp to $mail_server port { smtp, pop3 } \ tag INET_DMZ keep state Email traffic will now be passed as part of the INET_DMZ policy entry. The complete ruleset: # macros int_if = "dc0" dmz_if = "dc1" ext_if = "ep0" int_net = "10.0.0.0/24" dmz_net = "192.168.0.0/24" www_server = "192.168.0.5" mail_server = "192.168.0.10" table persist file "/etc/spammers" # classification -- classify packets based on the defined firewall # policy. rdr on $ext_if proto tcp from to port smtp \ tag SPAMD -> 127.0.0.1 port 8025 block all pass in on $int_if from $int_net tag LAN_INET keep state pass in on $int_if from $int_net to $dmz_net tag LAN_DMZ keep state pass in on $ext_if proto tcp to $www_server port 80 tag INET_DMZ keep state pass in on $ext_if proto tcp to $mail_server port { smtp, pop3 } \ tag INET_DMZ keep state # policy enforcement -- pass/block based on the defined firewall policy. pass in quick on $ext_if tagged SPAMD keep state pass out quick on $ext_if tagged LAN_INET keep state pass out quick on $dmz_if tagged LAN_DMZ keep state pass out quick on $dmz_if tagged INET_DMZ keep state Tagging Ethernet Frames Tagging can be performed at the Ethernet level if the machine doing the tagging/filtering is also acting as a bridge(4). By creating bridge(4) filter rules that use the tag keyword, PF can be made to filter based on the source/ destination MAC address. Bridge(4) rules are created using the brconfig(8) command. Example: # brconfig bridge0 rule pass in on fxp0 src 0:de:ad:be:ef:0 \ tag USER1 And then in pf.conf: pass in on fxp0 tagged USER1 ------------------------------------------------------------------------------ $OpenBSD: tagging.html,v 1.4 2004/05/07 01:55:24 nick Exp $ ============================================================================== PF: Logging ------------------------------------------------------------------------------ Table of Contents * Introduction * Reading a Log File * Filtering Log Output * Packet Logging Through Syslog ------------------------------------------------------------------------------ Introduction Packet logging in PF is done by pflogd(8) which listens on the pflog0 interface and writes packets to a log file (normally /var/log/pflog) in tcpdump(8) binary format. Filter rules that specify the log or log-all keyword are logged in this manner. Reading a Log File The log file written by pflogd is in binary format and cannot be read using a text editor. Tcpdump must be used to view the log. To view the log file: # tcpdump -n -e -ttt -r /var/log/pflog Note that using tcpdump(8) to watch the pflog file does not give a real-time display. A real-time display of logged packets is achieved by using the pflog0 interface: # tcpdump -n -e -ttt -i pflog0 NOTE: When examining the logs, special care should be taken with tcpdump's verbose protocol decoding (activated via the -v command line option). Tcpdump's protocol decoders do not have a perfect security history. At least in theory, a delayed attack could be possible via the partial packet payloads recorded by the logging device. It is recommended practice to move the log files off of the firewall machine before examining them in this way. Additional care should also be taken to secure access to the logs. By default, pflogd will record 96 bytes of the packet in the log file. Access to the logs could provide partial access to sensitive packet payloads (like telnet(1) or ftp(1) usernames and passwords). Filtering Log Output Because pflogd logs in tcpdump binary format, the full range of tcpdump features can be used when reviewing the logs. For example, to only see packets that match a certain port: # tcpdump -n -e -ttt -r /var/log/pflog port 80 This can be further refined by limiting the display of packets to a certain host and port combination: # tcpdump -n -e -ttt -r /var/log/pflog port 80 and host 192.168.1.3 The same idea can be applied when reading from the pflog0 interface: # tcpdump -n -e -ttt -i pflog0 host 192.168.4.2 Note that this has no impact on which packets are logged to the pflogd log file; the above commands only display packets as they are being logged. In addition to using the standard tcpdump(8) filter rules, OpenBSD's tcpdump filter language has been extended for reading pflogd output: * ip - address family is IPv4. * ip6 - address family is IPv6. * on int - packet passed through the interface int. * ifname int - same as on int. * rulenum num - the filter rule that the packet matched was rule number num. * action act - the action taken on the packet. Possible actions are pass and block. * reason res - the reason that action was taken. Possible reasons are match, bad-offset, fragment, short, normalize, and memory. * inbound - packet was inbound. * outbound - packet was outbound. Example: # tcpdump -n -e -ttt -i pflog0 inbound and action block and on wi0 This display the log, in real-time, of inbound packets that were blocked on the wi0 interface. Packet Logging Through Syslog In many situations it is desirable to have the firewall logs available in ASCII format and/or to send them to a remote logging server. All this can be accomplished with two small shell scripts, some minor changes of the OpenBSD configuration files, and syslogd(8), the logging daemon. Syslogd logs in ASCII and is also able to log to a remote logging server. First we have to create a user, pflogger, with a /sbin/nologin shell. The easiest way to create this user is with adduser(8). After creating the user pflogger, create the following two scripts: /etc/pflogrotate FILE=/home/pflogger/pflog5min.$(date "+%Y%m%d%H%M") kill -ALRM $(cat /var/run/pflogd.pid) if [ $(ls -l /var/log/pflog | cut -d " " -f 8) -gt 24 ]; then mv /var/log/pflog $FILE chown pflogger $FILE kill -HUP $(cat /var/run/pflogd.pid) fi /home/pflogger/pfl2sysl for logfile in /home/pflogger/pflog5min* ; do tcpdump -n -e -ttt -r $logfile | logger -t pf -p local0.info rm $logfile done Edit root's cron job: # crontab -u root -e Add the following two lines: # rotate pf log file every 5 minutes 0-59/5 * * * * /bin/sh /etc/pflogrotate Create a cron job for user pflogger: # crontab -u pflogger -e Add the following two lines: # feed rotated pflog file(s) to syslog 0-59/5 * * * * /bin/sh /home/pflogger/pfl2sysl Add the following line to /etc/syslog.conf: local0.info /var/log/pflog.txt If you also want to log to a remote log server, add the line: local0.info @syslogger Make sure host syslogger has been defined in the hosts(5) file. Create the file /var/log/pflog.txt to allow syslog to log to that file. # touch /var/log/pflog.txt Make syslogd notice the changes by restarting it: # kill -HUP $(cat /var/run/syslog.pid) All logged packets are now sent to /var/log/pflog.txt. If the second line is added they are sent to the remote logging host syslogger as well. The script /etc/pflogrotate now processes and then deletes /var/log/pflog so rotation of pflog by newsyslog(8) is no longer necessary and should be disabled. However, /var/log/pflog.txt replaces /var/log/pflog and rotation of it should be activated. Change /etc/newsyslog.conf as follows: #/var/log/pflog 600 3 250 * ZB /var/run/pflogd.pid /var/log/pflog.txt 600 7 * 24 PF will now log in ASCII to /var/log/pflog.txt. If so configured in /etc/ syslog.conf, it will also log to a remote server. The logging is not immediate but can take up to about 5-6 minutes (the cron job interval) before the logged packets appear in the file. ------------------------------------------------------------------------------ $OpenBSD: logging.html,v 1.15 2004/05/07 01:55:23 nick Exp $ ============================================================================== PF: Performance ------------------------------------------------------------------------------ "How much bandwidth can PF handle?" "How much computer do I need to handle my Internet connection?" There are no easy answers to those questions. For some applications, a 486/66 with a pair of good ISA NICs could filter and NAT close to 5Mbps, but for other applications a much faster machine with much more efficient PCI NICs might end up being insufficient. The real question is not the number of bits per second but rather the number of packets per second and the complexity of the ruleset. PF performance is determined by several variables: * Number of packets per second. Almost the same amount of processing needs to be done on a packet with 1500 byte payload as for a packet with a one byte payload. The number of packets per second determines the number of times the state table and, in case of no match there, filter rules have to be evaluated every second, determining the effective demand on the system. * Performance of your system bus. The ISA bus has a maximum bandwidth of 8MB /sec, and when the processor is accessing it, it has to slow itself to the effective speed of a 80286 running at 8MHz, no matter how fast the processor really is. The PCI bus has a much greater effective bandwidth, and has less impact on the processor. * Efficiency of your network card. Some network adapters are just more efficient than others. Realtek 8139 (rl(4)) based cards tend to be relatively poor performers while Intel 21143 (dc(4)) based cards tend to perform very well. For maximum performance, consider using gigabit Ethernet cards, even if not connecting to gigabit networks, as they have much more advanced buffering. * Complexity and design of your ruleset. The more complex your ruleset, the slower it is. The more packets that are filtered by keep state and quick rules, the better the performance. The more lines that have to be evaluated for each packet, the lower the performance. * Barely worth mentioning: CPU and RAM. As PF is a kernel-based process, it will not use swap space. So, if you have enough RAM, it runs, if not, it panics due to pool(9) exhaustion. Huge amounts of RAM are not needed -- 32MB should be plenty for close to 30,000 states, which is a lot of states for a small office or home application. Most users will find a "recycled" computer more than enough for a PF system -- a 300MHz system will move a very large number of packets rapidly, at least if backed up with good NICs and a good ruleset. People often ask for PF benchmarks. The only benchmark that counts is your system performance in your environment. A benchmark that doesn't replicate your environment will not properly help you plan your firewall system. The best course of action is to benchmark PF for yourself under the same, or as close as possible to, network conditions that the actual firewall would experience running on the same hardware the firewall would use. PF is used in some very large, high-traffic applications, and the developers are "power users" of PF. Odds are, it will do very well for you. ------------------------------------------------------------------------------ $OpenBSD: perf.html,v 1.14 2004/05/07 01:55:24 nick Exp $ ============================================================================== PF: Issues with FTP ------------------------------------------------------------------------------ Table of Contents * FTP Modes * FTP Client Behind the Firewall * PF "Self-Protecting" an FTP Server * FTP Server Protected by an External PF Firewall Running NAT * More Information on FTP ------------------------------------------------------------------------------ FTP Modes FTP is a protocol that dates back to when the Internet was a small, friendly collection of computers and everyone knew everyone else. At that time the need for filtering or tight security wasn't necessary. FTP wasn't designed for filtering, for passing through firewalls, or for working with NAT. You can use FTP in one of two ways: passive or active. Generally, the choice of active or passive is made to determine who has the problem with firewalling. Realistically, you will have to support both to have happy users. With active FTP, when a user connects to a remote FTP server and requests information or a file, the FTP server makes a new connection back to the client to transfer the requested data. This is called the data connection. To start, the FTP client chooses a random port to receive the data connection on. The client sends the port number it chose to the FTP server and then listens for an incoming connection on that port. The FTP server then initiates a connection to the client's address at the chosen port and transfers the data. This is a problem for users attempting to gain access to FTP servers from behind a NAT gateway. Because of how NAT works, the FTP server initiates the data connection by connecting to the external address of the NAT gateway on the chosen port. The NAT machine will receive this, but because it has no mapping for the packet in its state table, it will drop the packet and won't deliver it to the client. With passive mode FTP (the default mode with OpenBSD's ftp(1) client), the client requests that the server pick a random port to listen on for the data connection. The server informs the client of the port it has chosen, and the client connects to this port to transfer the data. Unfortunately, this is not always possible or desirable because of the possibility of a firewall in front of the FTP server blocking the incoming data connection. OpenBSD's ftp(1) uses passive mode by default; to force active mode FTP, use the -A flag to ftp, or set passive mode to "off" by issuing the command "passive off" at the "ftp>" prompt. FTP Client Behind the Firewall As indicated earlier, FTP does not go through NAT and firewalls very well. Packet Filter provides a solution for this situation by redirecting FTP traffic through an FTP proxy server. This process acts to "guide" your FTP traffic through the NAT gateway/firewall. The FTP proxy used by OpenBSD and PF is ftp-proxy(8). To activate it, put something like this in the NAT section of pf.conf: rdr on $int_if proto tcp from any to any port 21 -> 127.0.0.1 \ port 8021 The explanation of this line is: "Traffic on the internal interface is redirected to the proxy server running on this machine which is listening at port 8021". Hopefully it is apparent the proxy server has to be started and running on the OpenBSD box. This is done by inserting the following line in /etc/inetd.conf: 127.0.0.1:8021 stream tcp nowait root /usr/libexec/ftp-proxy \ ftp-proxy and either rebooting the system or sending a 'HUP' signal to inetd(8). One way to send the 'HUP' signal is with the command: kill -HUP `cat /var/run/inetd.pid` You will note that ftp-proxy is listening on port 8021, the same port the above rdr statement is sending FTP traffic to. The choice of port 8021 is arbitrary, though 8021 is a good choice as it is not defined for any other application. Please note that ftp-proxy(8) is to help FTP clients behind a PF filter; it is not used to handle an FTP server behind a PF filter. PF "Self-Protecting" an FTP Server In this case, PF is running on the FTP server itself rather than a dedicated firewall computer. When servicing a passive FTP connection, FTP will use a randomly chosen, high TCP port for incoming data. By default, OpenBSD's native FTP server ftpd(8) uses the range 49152 to 65535. Obviously, these must be passed through the filter rules, along with port 21 (the FTP control port): pass in on $ext_if proto tcp from any to any port 21 keep state pass in on $ext_if proto tcp from any to any port > 49151 \ keep state Note that if you desire, you can tighten up that range of ports considerably. In the case of the OpenBSD ftpd(8) program, that is done using the sysctl(8) variables net.inet.ip.porthifirst and net.inet.ip.porthilast. FTP Server Protected by an External PF Firewall Running NAT In this case, the firewall must redirect traffic to the FTP server in addition to not blocking the required ports. For the sake of discussion, we will assume the FTP server in question is again the standard OpenBSD ftpd(8), using the default range of ports. Here is an example subset of rules which would accomplish this: ftp_server = "10.0.3.21" rdr on $ext_if proto tcp from any to any port 21 -> $ftp_server \ port 21 rdr on $ext_if proto tcp from any to any port 49152:65535 -> \ $ftp_server port 49152:65535 # in on $ext_if pass in quick on $ext_if proto tcp from any to $ftp_server \ port 21 keep state pass in quick on $ext_if proto tcp from any to $ftp_server \ port > 49151 keep state # out on $int_if pass out quick on $int_if proto tcp from any to $ftp_server \ port 21 keep state pass out quick on $int_if proto tcp from any to $ftp_server \ port > 49151 keep state More Information on FTP More information on filtering FTP and how FTP works in general can be found in this whitepaper: * FTP Reviewed ------------------------------------------------------------------------------ $OpenBSD: ftp.html,v 1.14 2004/05/07 01:55:23 nick Exp $ ============================================================================== PF: Authpf: User Shell for Authenticating Gateways ------------------------------------------------------------------------------ Table of Contents * Introduction * Configuration + Linking Authpf into the Main Ruleset + Configuring Loaded Rules + Access Control Lists + Assigning Authpf as a User's Shell * Seeing Who is Logged In * More Information * Example ------------------------------------------------------------------------------ Introduction Authpf(8) is a user shell for authenticating gateways. An authenticating gateway is just like a regular network gateway (a.k.a. a router) except that users must first authenticate themselves to the gateway before it will allow traffic to pass through it. When a user's shell is set to /usr/sbin/authpf (i.e., instead of setting a user's shell to ksh(1), csh(1), etc) and the user logs in using SSH, authpf will make the necessary changes to the active pf(4) ruleset so that the user's traffic is passed through the filter and/or translated using Network Address Translation or redirection. Once the user logs out or their session is disconnected, authpf will remove any rules loaded for the user and kill any stateful connections the user has open. Because of this, the ability of the user to pass traffic through the gateway only exists while the user keeps their SSH session open. Authpf alters the pf(4) ruleset by adding rules to a named ruleset attached to an anchor point. Each time a user authenticates, authpf creates a new named ruleset and loads the preconfigured filter, nat, binat, and rdr rules into it. The rules that authpf loads can be configured on a per-user or global basis. Example uses of authpf include: * Requiring users to authenticate before allowing Internet access. * Granting certain users -- such as administrators -- access to restricted parts of the network. * Allowing only known users to access the rest of the network or Internet from a wireless network segment. * Allowing workers from home, on the road, etc., access to resources on the company network. Users outside the office can not only open access to the company network, but can also be redirected to particular resources (e.g., their own desktop) based on the username they authenticate with. * In a setting such as a library or other place with public Internet terminals, PF may be configured to allow limited Internet access to guest users. Authpf can then be used to provide registered users with complete access. Authpf logs the username and IP address of each user who authenticates successfully as well as the start and end times of their login session via syslogd(8). By using this information, an administrator can determine who was logged in when and also make users accountable for their network traffic. Configuration The basic steps needed to configure authpf are outlined here. For a complete description of authpf configuration, please refer to the authpf man page. Linking Authpf into the Main Ruleset Authpf is linked into the main ruleset by using anchor rules: nat-anchor authpf rdr-anchor authpf binat-anchor authpf anchor authpf Wherever the anchor rules are placed within the ruleset is where PF will branch off from the main ruleset to evaluate the authpf rules. It's not necessary for all four anchor rules to be present; for example, if authpf hasn't been setup to load any nat rules, the nat-anchor rule can be omitted. Configuring Loaded Rules Authpf loads its rules from one of two files: * /etc/authpf/users/$USER/authpf.rules * /etc/authpf/authpf.rules The first file contains rules that are only loaded when the user $USER (which is replaced with the user's username) logs in. The per-user rule configuration is used when a specific user -- such as an administrator -- requires a set of rules that is different than the default set. The second file contains the default rules which are loaded for any user that doesn't have their own authpf.rules file. If the user-specific file exists, it will override the default file. At least one of the files must exist or authpf will not run. Filter and translation rules have the same syntax as in any other PF ruleset with one exception: Authpf allows for the use of two predefined macros: * $user_ip - the IP address of the logged in user * $user_id - the username of the logged in user It's recommended practice to use the $user_ip macro to only permit traffic through the gateway from the authenticated user's computer. Access Control Lists Users can be prevented from using authpf by creating a file in the /etc/authpf /banned/ directory and naming it after the username that is to be denied access. The contents of the file will be displayed to the user before authpf disconnects them. This provides a handy way to notify the user of why they're disallowed access and who to contact to have their access restored. Conversely, it's also possible to allow only specific users access by placing usernames in the /etc/authpf/authpf.allow file. If the /etc/authpf/ authpf.allow file does not exist or "*" is entered into the file, then authpf will permit access to any user who successfully logs in via SSH as long as they are not explicitly banned. If authpf is unable to determine if a username is allowed or denied, it will print a brief message and then disconnect the user. An entry in /etc/authpf/ banned/ always overrides an entry in /etc/authpf/authpf.allow. Assigning Authpf as a User's Shell In order for authpf to work it must be assigned as the user's login shell. When the user successfully authenticates to sshd(8), authpf will be executed as the user's shell. It will then check if the user is allowed to use authpf, load the rules from the appropriate file, etc. There are a couple ways of assigning authpf as a user's shell: 1. Manually for each user using chsh(1), vipw(8), useradd(8), usermod(8), etc. 2. By assigning users to a login class and changing the class's shell option in /etc/login.conf. Seeing Who is Logged In Once a user has successfully logged in and authpf has adjusted the PF rules, authpf changes its process title to indicate the username and IP address of the logged in user: # ps -ax | grep authpf 23664 p0 Is+ 0:00.11 -authpf: charlie@192.168.1.3 (authpf) Here the user charlie is logged in from the machine 192.168.1.3. By sending a SIGTERM signal to the authpf process, the user can be forcefully logged out. Authpf will also remove any rules loaded for the user and kill any stateful connections the user has open. # kill -TERM 23664 More Information For a complete description of authpf operation, please refer to the authpf man page. Example Authpf is being used on an OpenBSD gateway to authenticate users on a wireless network which is part of a larger campus network. Once a user has authenticated, assuming they're not on the banned list, they will be permitted to SSH out and to browse the web (including secure web sites) in addition to accessing either of the campus DNS servers. The /etc/authpf/authpf.rules file contains the following rules: wifi_if = "wi0" dns_servers = "{ 10.0.1.56, 10.0.2.56 }" pass in quick on $wifi_if proto udp from $user_ip to $dns_servers \ port domain keep state pass in quick on $wifi_if proto tcp from $user_ip to port { ssh, http, \ https } flags S/SA keep state The administrative user charlie needs to be able to access the campus SMTP and POP3 servers in addition to surfing the web and using SSH. The following rules are setup in /etc/authpf/users/charlie/authpf.rules: wifi_if = "wi0" smtp_server = "10.0.1.50" pop3_server = "10.0.1.51" dns_servers = "{ 10.0.1.56, 10.0.2.56 }" pass in quick on $wifi_if proto udp from $user_ip to $dns_servers \ port domain keep state pass in quick on $wifi_if proto tcp from $user_ip to $smtp_server \ port smtp flags S/SA keep state pass in quick on $wifi_if proto tcp from $user_ip to $pop3_server \ port pop3 flags S/SA keep state pass in quick on $wifi_if proto tcp from $user_ip to port { ssh, http, \ https } flags S/SA keep state The main ruleset -- located in /etc/pf.conf -- is setup as follows: # macros wifi_if = "wi0" ext_if = "fxp0" scrub in all # filter block drop all pass out quick on $ext_if proto tcp from $wifi_if:network flags S/SA \ modulate state pass out quick on $ext_if proto { udp, icmp } from $wifi_if:network \ keep state pass in quick on $wifi_if proto tcp from $wifi_if:network to $wifi_if \ port ssh flags S/SA keep state anchor authpf in on $wifi_if The ruleset is very simple and does the following: * Block everything (default deny). * Pass outgoing TCP, UDP, and ICMP traffic on the external interface from the wireless network. * Pass incoming SSH traffic from the wireless network destined for the gateway itself. This rule is necessary to permit users to log in. * Create the anchor point "authpf" for incoming traffic on the wireless interface. The idea behind the main ruleset is to block everything and allow the least amount of traffic through as possible. Traffic is free to flow out on the external interface but is blocked from entering the wireless interface by the default deny policy. Once a user authenticates, their traffic is permitted to pass in on the wireless interface and to then flow through the gateway into the rest of the network. The quick keyword is used throughout so that PF doesn't have to evaluate each named ruleset when a new connection passes through the gateway. ------------------------------------------------------------------------------ $OpenBSD: authpf.html,v 1.7 2004/05/07 01:55:23 nick Exp $ ============================================================================== PF: Example: Firewall for Home or Small Office ------------------------------------------------------------------------------ Table of Contents * The Scenario + The Network + The Objective + Preparation * The Ruleset + Macros + Options + Scrub + Network Address Translation + Redirection + Filter Rules * The Complete Ruleset ------------------------------------------------------------------------------ The Scenario In this example, PF is running on an OpenBSD machine acting as a firewall and NAT gateway for a small network in a home or office. The overall objective is to provide Internet access to the network and to allow limited access to the firewall machine from the Internet. This document will go through a complete ruleset that does just that. The Network The network is setup like this: [ COMP1 ] [ COMP3 ] | | ADSL ---+------+-----+------- fxp0 [ OpenBSD ] ep0 -------- ( Internet ) | [ COMP2 ] There are a number of computers on the internal network; the diagram shows three but the actual number is irrelevant. These computers are regular workstations used for web surfing, email, chatting, etc., except for COMP3 which is also running a small web server. The internal network is using the 192.168.0.0 / 255.255.255.0 network block. The OpenBSD router is a Pentium 100 with two network cards: a 3com 3c509B (ep0) and an Intel EtherExpress Pro/100 (fxp0). The router has an ADSL connection to the Internet and is using NAT to share this connection with the internal network. The IP address on the external interface is dynamically assigned by the Internet Service Provider. The Objective The objectives are: * Provide unrestricted Internet access to each internal computer. * Use a "default deny" filter ruleset. * Allow the following incoming traffic to the firewall from the Internet: + SSH (TCP port 22): this will be used for external maintenance of the firewall machine. + Auth/Ident (TCP port 113): used by some services such as SMTP and IRC. + ICMP Echo Requests: the ICMP packet type used by ping(8). * Redirect TCP port 80 connection attempts (which are attempts to access a web server) to computer COMP3. Also, permit TCP port 80 traffic destined for COMP3 through the firewall. * Log filter statistics on the external interface. * By default, reply with a TCP RST or ICMP Unreachable for blocked packets. * Make the ruleset as simple and easy to maintain as possible. Preparation This document assumes that the OpenBSD host has been properly configured to act as a router, including verifying IP networking setup, Internet connectivity, and setting net.inet.ip.forwarding to "1". The Ruleset The following will step through a ruleset that will accomplish the above goals. Macros The following macros are defined to make maintenance and reading of the ruleset easier: int_if = "fxp0" ext_if = "ep0" tcp_services = "{ 22, 113 }" icmp_types = "echoreq" priv_nets = "{ 127.0.0.0/8, 192.168.0.0/16, 172.16.0.0/12, 10.0.0.0/8 }" comp3 = "192.168.0.3" The first two lines define the network interfaces that filtering will happen on. The third and fourth lines list the TCP port numbers of the services that will be opened up to the Internet (SSH and ident/auth) and the ICMP packet types that will be permitted to reach the firewall machine. The fifth line defines the loopback and RFC 1918 address blocks. Finally, the last line defines the IP address of COMP3. Note: If the ADSL Internet connection required PPPoE, then filtering and NAT would have to take place on the tun0 interface and not on ep0. Options The following two options will set the default response for block filter rules and turn statistics logging "on" for the external interface: set block-policy return set loginterface $ext_if Scrub There is no reason not to use the recommended scrubbing of all incoming traffic, so this is a simple one-liner: scrub in all Network Address Translation To perform NAT for the entire internal network the following nat rule is used: nat on $ext_if from $int_if:network to any -> ($ext_if) Since the IP address on the external interface is assigned dynamically, parenthesis are placed around the translation interface so that PF will notice when the address changes. Redirection The first redirection rule needed is for ftp-proxy(8) so that FTP clients on the local network can connect to FTP servers on the Internet. rdr on $int_if proto tcp from any to any port 21 -> 127.0.0.1 port 8021 Note that this rule will only catch FTP connections to port 21. If users regularly connect to FTP servers on other ports, then a list should be used to specify the destination port, for example: from any to any port { 21, 2121 }. The second redirection rule catches any attempts by someone on the Internet to connect to TCP port 80 on the firewall. Legitimate attempts to access this port will be from users trying to access the network's web server. These connection attempts need to be redirected to COMP3: rdr on $ext_if proto tcp from any to any port 80 -> $comp3 Filter Rules Now the filter rules. Start with the default deny: block all At this point nothing will go through the firewall, not even from the internal network. The following rules will open up the firewall as per the objectives above as well as open up any necessary virtual interfaces. Every Unix system has a "loopback" interface. It's a virtual network interface that is used by applications to talk to each other inside the system. In general, all traffic should be passed on the loopback interface. On OpenBSD, the loopback interface is lo(4). pass quick on lo0 all Next, the RFC 1918 addresses will be blocked from entering or exiting the external interface. These addresses should never appear on the public Internet, and filtering them will ensure that the router does not "leak" these addresses out from the internal network and also block any incoming packets with a source address in one of those networks. block drop in quick on $ext_if from $priv_nets to any block drop out quick on $ext_if from any to $priv_nets Note that block drop is used to tell PF not to respond with a TCP RST or ICMP Unreachable packet. Since the RFC 1918 addresses don't exist on the Internet, any packets sent to those addresses will never make it there anyways. The quick option is used to tell PF not to bother evaluating the rest of the filter rules if one of the above rules matches; packets to or from the $priv_nets networks will be immediately dropped. Now open the ports used by those network services that will be available to the Internet: pass in on $ext_if inet proto tcp from any to ($ext_if) \ port $tcp_services flags S/SA keep state Specifying the network ports in the macro $tcp_services makes it simple to open additional services to the Internet by simply editing the macro and reloading the ruleset. UDP services can also be opened up by creating a $udp_services macro and adding a filter rule, similar to the one above, that specifies proto udp. In addition to having an rdr rule which passes the web server traffic to COMP3, we MUST also pass this traffic through the firewall: pass in on $ext_if proto tcp from any to $comp3 port 80 \ flags S/SA synproxy state For an added bit of safety, we'll make use of the TCP SYN Proxy to further protect the web server. ICMP traffic must now be passed: pass in inet proto icmp all icmp-type $icmp_types keep state Similar to the $tcp_services macro, the $icmp_types macro can easily be edited to change the types of ICMP packets that will be allowed to reach the firewall. Note that this rule applies to all network interfaces. Now traffic must be passed to and from the internal network. We'll assume that the users on the internal network know what they are doing and aren't going to be causing trouble. This is not necessarily a valid assumption; a much more restrictive ruleset would be appropriate for some environments. pass in on $int_if from $int_if:network to any keep state The above rule will permit any internal machine to send packets through the firewall; however, it will not permit the firewall to initiate a connection to an internal machine. Is this a good idea? That depends on some of the finer details of the network setup. If the firewall is also a DHCP server, it may need to "ping" an address to verify its availability before assigning it. Permitting the firewall to connect to the internal network also allows someone who has ssh'ed into the firewall from the Internet to then access machines on the network. Keep in mind that not allowing the firewall to communicate directly to the network is not a large security benefit; if someone gets access to the firewall they can probably alter the filter rules anyways. By adding the following rule, the firewall will be able to initiate connections to the internal network: pass out on $int_if from any to $int_if:network keep state Note that if both of these lines are in place, the keep state option is not needed; all packets will be able to pass through the internal interface because there is a rule to pass packets in both directions. However, if the pass out line is not included, the pass in line must include keep state. There is also some performance benefit to keeping state: State tables are checked before rules are evaluated, and if a state match is found, the packet is passed through the firewall without going through ruleset evaluation. This can offer a performance benefit on a heavily loaded firewall, though in a system this simple it is unlikely to generate enough load to matter. Finally, pass traffic out on the external interface: pass out on $ext_if proto tcp all modulate state flags S/SA pass out on $ext_if proto { udp, icmp } all keep state TCP, UDP, and ICMP traffic is permitted to exit the firewall towards the Internet. State information is kept so that the returning packets will be passed in through the firewall. The Complete Ruleset # macros int_if = "fxp0" ext_if = "ep0" tcp_services = "{ 22, 113 }" icmp_types = "echoreq" priv_nets = "{ 127.0.0.0/8, 192.168.0.0/16, 172.16.0.0/12, 10.0.0.0/8 }" comp3 = "192.168.0.3" # options set block-policy return set loginterface $ext_if # scrub scrub in all # nat/rdr nat on $ext_if from $int_if:network to any -> ($ext_if) rdr on $int_if proto tcp from any to any port 21 -> 127.0.0.1 \ port 8021 rdr on $ext_if proto tcp from any to any port 80 -> $comp3 # filter rules block all pass quick on lo0 all block drop in quick on $ext_if from $priv_nets to any block drop out quick on $ext_if from any to $priv_nets pass in on $ext_if inet proto tcp from any to ($ext_if) \ port $tcp_services flags S/SA keep state pass in on $ext_if proto tcp from any to $comp3 port 80 \ flags S/SA synproxy state pass in inet proto icmp all icmp-type $icmp_types keep state pass in on $int_if from $int_if:network to any keep state pass out on $int_if from any to $int_if:network keep state pass out on $ext_if proto tcp all modulate state flags S/SA pass out on $ext_if proto { udp, icmp } all keep state ------------------------------------------------------------------------------ $OpenBSD: example1.html,v 1.15 2004/05/15 02:34:02 nick Exp $