This weekend, I spent some time to replace my aged Linksys WRT54G wireless router, which is running DD-WRT. The WRT54G is slow by today’s wireless standards and since I sync my iOS devices wirelessly, the speed was getting quite unbearable. When I bought my Macbook Pro in 2007, it already has draft 802.11n support and fast-forward to 2012, my iPad (1st generation) and iPhone 5 both support the 5GHz band.
The ASUS RT-N56U wireless router ranks up there on wireless performance, and the “feature” I was really after was a router that can run an alternative firmware such as Tomato or DD-WRT. The really good news is, I figured out how to get the functionality I wanted while still using the official ASUS firmware.
For proper reviews and better photos, you might want to check out these other reviews:
- SmallNetBuilder: ASUS RT-N56U Black Diamond Dual-Band Gigabit Wireless-N Router Reviewed
- FoxNetwork: ASUS RT-N56U or hardware NAT acceleration
(I quite like their professionally taken product photos and their reverse-engineering work)
Read on to find my short review, as well as how you can run your own programs on the router without using a third-party firmware.
A Geek’s Review
It is a dual-band router, which means it operates on both the 2.4GHz and 5GHz frequency bands simultaneously. Its antennas are built-in (actually on the PCB) so you won’t be able to swap them for higher gain ones.
The router has no wall-mounting holes, unfortunately, but it has a flat back so it can be laid on a flat surface. It comes with a stand that you can use to prop it up and face in a particular direction, but I chose not attach it. There have been reports of instability due to heat build up, so I do not recommend that you stack it on top of other equipment. Use some type of spacer if you have to, for airflow.
It uses a “non-standard” small diameter barrel jack which accepts 19V @ 1.58A, so if you’re planning on using an alternative power supply, or a Power-over-Ethernet (POE) injector, you will have some work to do.
There are a few firmware alternatives available for the RT-N56U, but DD-WRT is not one of them. The most popular one seems to be Asuswrt-Merlin. There is another one that was posted on the DD-WRT forum: https://code.google.com/p/rt-n56u/
Actually, my requirements are quite simple. I just need a DHCP forwarder (which DD-WRT had) to forward requests to my main DHCP server and I need to be able to run mDNS Repeater to repeat mDNS packets between the wireless and wired subnets. It turns out that I could fulfill both of these requirements without installing an alternative firmware.
What is ASUSWRT?
ASUS created a unified firmware for their routers called ASUSWRT. The whole thing, including the userland, is open source (except for proprietary kernel modules from the chip manufacturer), which is really nice. I can’t find much information about which routers can be upgraded to ASUSWRT, but the newer routers such as RT-N66U, RT-N56U, and some older ones like RT-N16 are supported.
So how can you tell if your router supports ASUSWRT? ASUS doesn’t explicitly advertise this, but on the firmware download page for your router, the ASUSWRT firmware can be identified by having at least version 188.8.131.52.x and above, or there might be a hint of it in the description (as shown here):
For routers with USB ports, ASUS has moved “Download Master” (a program that controls downloads on your router) to a USB application. A USB application is one that runs off USB storage, and that makes sense since you need to attach some form of storage to download your files to. The same goes for a “media server”, which I assume is a DLNA server that serves your media files. This way, the firmware image can be made small enough to be used by most routers and still not compromise on functionality. The USB application can also be updated independently from the router firmware.
To run our own programs, we will tap this USB application functionality baked into the ASUSWRT firmware.
Running Programs on the ASUSWRT
When a USB storage device is inserted into the router’s USB port, the
rc system daemon mounts the partition and checks for the existence of an
asusware/.asusrouter script on the mount point. If it exists, the asusware folder is then symlinked to
/tmp/opt (and also
/opt) and the script is executed. Since this is all open source, you can find the relevant code in the
mount_partition function in
.asusrouter auto-run script is created as part of the Optware installation when you try to install one of the USB applications from the router’s web UI, which you can also manually do from the router’s telnet interface. The asuswrt-merlin github wiki contains more step-by-step guides with screenshots. However, installing Optware is not necessary to get your programs to run – the auto-run script alone will suffice.
Put the commands you wish to execute in
asusware/.asusrouter on your USB storage device. Like any shell script, make sure it has
#!/bin/sh as its first line and that the file uses UNIX line endings. The filesystem can be anything supported by the kernel – ext2, ext3 or fat. If you are using a filesystem that implements Linux permissions (such as ext2 or ext3), be sure to set the script as executable.
One caveat when running network programs (like DHCP forwarder or mDNS repeater) is that you need to wait until everything has been initialized. ASUS does that by polling the
success_start_service NVRAM variable with this bash snippet:
i=0 while [ $i -le 20 ]; do success_start_service=`nvram get success_start_service` if [ "$success_start_service" == "1" ]; then break fi i=$(($i+1)) echo "autorun APP: wait $i seconds..."; sleep 1 done
When the router starts up, it automatically detects plugged-in devices, so I just left a small USB stick permanently in one of the ports.
Cross-compiling Programs for the ASUSWRT
ASUS was nice enough to include the cross-compilation toolchain in the source code. You can find the source code (which also contains the toolchain) on the very same ASUS download page for the firmware.
The source code has a
README.txt that describes how to setup your development environment, which I assume you have already read or be familiar with. To perform the compilations described here, you need only ensure that your
$PATH contains the directory to the cross-compilation toolchain. I unpacked the source code in my home directory, so I just need this line:
To check that it works correctly, you should be able to execute
DHCP forwarder requires some minor fix up to get it to compile properly, or maybe I’m doing something wrong. I’m using version 0.10, the latest version available on the site. It’s a standard configure and make program, so it’s the
configure command-line that is important:
./configure --host=mipsel-linux-uclibc --enable-release
After configure has done its work, some changes need to be made to the generated
config.h file for successful compilation. Open
config.h and search for the term
"rpl_malloc". You will find a
#define that replaces
rpl_malloc. This line needs to be commented (or removed) since
malloc is available in uClibc.
/* Define to rpl_malloc if the replacement function should be used. */ //#define malloc rpl_malloc
After commenting that line, simply run
make and the
dhcp-fwd binary (among other things) will be produced.
This one is easy – it invokes only
gcc and uses
I have also uploaded the binary onto the repository’s download page, so that you can avoid having to recompile it yourself.
Setting Up DHCP Forwarder
ASUSWRT uses dnsmasq to forward DNS queries and provide DHCP service. In order to install the DHCP forwarder, the DHCP service needs to be disabled. This can be done from the web interface under “LAN”, and selecting the “DHCP Server” tab. ASUSWRT will then replace the DHCP configuration lines in
no-dhcp-interface=br0 and more importantly, stop listening on the DHCP port.
dhcp-fwd.conf is copied from the DD-WRT router and the interface names have been changed for the RT-N56U, where
br0 is the wireless & LAN ports and
eth3 is the WAN port:
user nobody group nobody chroot /var/run/dhcp-fwd logfile /tmp/dhcp-fwd.log loglevel 1 pidfile /var/run/dhcp-fwd.pid ulimit core 0 ulimit stack 64K ulimit data 32K ulimit rss 200K ulimit nproc 0 ulimit nofile 0 ulimit as 0 if br0 true false true if eth3 false true true name br0 ws-c server ip 192.168.0.1
If you’re feeling adventurous, the router interface names and IP addresses can be retrieved from NVRAM using the
nvram command. Here’s a bash snippet that obtains the LAN & WAN interface names, as well as the assigned WAN gateway address:
LAN_IFNAME=`nvram get lan_ifname` WAN_IFNAME=`nvram get wan_ifname` WAN_GATEWAY=`nvram get wan_gateway`
It seems like ASUS routers that run ASUSWRT are already quite flexible. If you do not need the additional features offered by alternative firmwares, then this hack is just right for you.
Have fun hacking your ASUS router!
Update 21-Apr-13: After upgrading to firmware version 184.108.40.206.360, I spent an entire evening getting my configuration to work. The router is configured to consult a RADIUS server (reachable through the WAN port), but the RADIUS server never gets the request. I have to go to the RADIUS Setting page and click Apply to “wake it up” or something. I noticed that doing this restarts
rt2860apd, so I tried to find a command I could call from the
.asusrouter script to trigger this. It was a quick hack, but I found that calling
/sbin/restart_wireless does the job. I reconfigured everything from scratch, so I didn’t have time to investigate if it was an ASUSWRT bug, or if starting
dhcp-fwd affected something. As long as my wireless is up, I’m happy leaving it as-is.
Update 28-Dec-18: I have published an updated post with instructions for newer ARM-based routers like the RT-AC68U.