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bycn82

2 Mar. 2015

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[[!toc  levels=3]]

# Introduction
Ipfw is a controlling utility for ipfw/ipacct facilities for FreeBSD 2.0 which released in November, 1994. After 20 years of evolution. it becomes a stateful firewall. It is comprised of several components, e.g. the kernel firewall filter rule processor and its integrated packet accounting facility, the logging facility, NAT, the dummynet(4) traffic shaper, a forward facility, a bridge facility, and an ipstealth facility. It is one of the most advanced opensource firewall.

DragonflyBSD is a logical continuation of the FreeBSD 4.x series, DragonFly's development has diverged significantly from FreeBSD's, e.g. a new Light Weight Kernel Threads implementation (LWKT), a lightweight ports/messaging system,

In DragonFly, each CPU has its own thread scheduler. Upon creation, threads are assigned to processors and are never preemptively switched from one processor to another; they are only migrated by the passing of an inter-processor interrupt (IPI) message between the CPUs involved. Inter-processor thread scheduling is also accomplished by sending asynchronous IPI messages. One advantage to this clean compartmentalization of the threading subsystem is that the processors' on-board caches in Symmetric Multiprocessor Systems do not contain duplicated data, allowing for higher performance by giving each processor in the system the ability to use its own cache to store different things to work on.

The LWKT subsystem is being employed to partition work among multiple kernel threads (for example in the networking code there is one thread per protocol per processor), reducing competition by removing the need to share certain resources among various kernel tasks.

The ipfw was rewritten from scratch for DragonflyBSD and named 'ipfw3', it is in modular design, and inherited the "SMP-Friendly" feature of DragonflyBSD's LWKT, it is a lockless and stateful firewall.

## Brief notes on design
Ipfw3 was in modular design. all the functionalities are implemented in different loadable modules, it can be loaded when it is required. the core framework of the ipfw3 only comes with default'accept' or 'deny' actions. by triggering below command, the core module will be loaded.

        kldload ipfw3

the fundamental core framework is loaded now. 

More basic firewall filtering features like 'filtering based on source IP' are implemented in basic module, so basic module need to be loaded before we start to the features. and below is the command to load the basic module, the basic module is relying on the core framework, so the core framework will be loaded automatically if it is not loaded yet,

        kldload ipfw3_basic

The basic module is loaded now. then the user can start to use the filters which was implemented in the basic module. besides the basic module, there are layer2 module, layer4 module, in-kernel NAT module, dummynet module.

Each module contains 2 parts. library in user-space which will be loaded and parse the command line into rules. and kernel space portion will be invoked when the traffic hit the firewall and it will trigger the correct action according to the firewall rules.

## Compare with FreeBSD's IPFW
Ipfw3 inherited all feature from FreeBSD's ipfw, and lots of new features are introduced from PF or other rivals.

**Much more extensible**

Every filter/action needs to be identified using ID, but there are only 8 bits space to store the ID, so theoretically it can support 256 filters/actions in maximum in FreeBSD' ipfw. While in ipfw3, the space for ID are still the same, but one space introduced to keep the module's ID, so theoretically ipfw3 can have 256 modules and 256 filter/action in each module.

And in ipfw3, both user-space library and kernel space module are implemented with a simple interface, it is quite easy to build your own filter/module by following the interface.

**Much more concise**

the rules of ipfw3 are much more concise. for example, the simple rule command like 

    ipfw add allow ip from any to any
   
the "from any to any" actually is just try to make the rule more human-readable. In ipfw3 we support the syntax of FreeBSD's ipfw, but we recommend to use simplified version as below:

    #1. ipfw3 add allow all 
    #2. ipfw3 add allow icmp from 1.1.1.1
    #3. ipfw3 add allow tcp via em0

**Higher Performance**

All modern CPUs are having mutil-cores, and each core are running independently. So the LWKT of DragonflyBSD is the best way to fully utilize the CPU power. by duplicating the environment for each CPU, all the CPU can run as fast as it can without any interference. So it is a lockless and stateful firewall.


# Features

## Core Framework

Below actions are directly supported from the core framework.

**accept**  -- accept the traffic

**deny**  -- deny the traffic

the default action of the firewall was compiled in the core framework. but it still can be interfered by below sysctl when the module was loading into the kernel.

    sysctl net.filters_default_to_accept

## Basic Module

Below filter/actions are supported in basic module.

**proto** -- matches traffic protocol, it is implicit after the action.

**from** -- matches the source.

Filter 'from' supports multiple type of parameters.

    from 8.8.8.8        -- match traffic from IP 8.8.8.8
    from table 1        -- match traffic where source IP found in table 1
    from any            -- not filtering
    from me             -- match traffic from the host
    from 192.168.1.0/24 -- match traffic from the IP range
 
**to** -- matches the destination.

Filter 'to' supports same parameters as filter 'from'

**count** -- action count the traffic

**skipto** -- skipto another line in the rules

**forward** -- forward the current traffic to a destination

**in** -- matches the in direction traffic

**out** -- matches the out direction traffic

**via** -- matches the traffic go throught an interface

**xmit** -- matches the out direction traffic thought an interface

**recv** -- matches the in direction traffic thought an interface

**src-port** --matches the src port of TCP/UDP traffic

**dst-port** --matches the dst port of TCP/UDP traffic

**prob** -- randomly match the traffic

**keep-state** -- setup a state in current CPU only

**check-state** -- loop the state table current CPU, match if its state exists

**tag** -- add a tag the traffic

**untag** -- remove the tag from the traffic

**tagged** -- matched the traffic with the tag

**//** -- append some comment at the end of the rule

## Layer2 Module

        O_LAYER2_LAYER2,
        O_LAYER2_MAC,
        O_LAYER2_MAC_TYPE,
        O_LAYER2_MAC_SRC,               /* from with layer2     */
        O_LAYER2_MAC_DST,               /* to   with layer2     */
        O_LAYER2_MAC_SRC_LOOKUP,        /* from table N +layer2 */
        O_LAYER2_MAC_DST_LOOKUP,        /* to   table N +layer2 */
        
## Layer4 Module

        O_LAYER4_TCPFLAG,
        O_LAYER4_UID,
        O_LAYER4_GID,
        O_LAYER4_ESTABLISHED,
        O_LAYER4_BPF,                   /* bpf syntax filter */
        
## NAT Module

        O_NAT_NAT,
        
## Dummynet3 Module

        O_DUMMYNET_PIPE,
        O_DUMMYNET_QUEUE,

## Advanced Features

**Lookup Table**

**Enhanced Forwarding**

**General BPF Filtering**

**Stateful**

**In-Kernel NAT**