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Its been a while since I did any IPCam stuff, but I’ve now got most of the bits I needed together again, as well as a new laptop for dev work (curse the thieves that stole my last one!)

As we recall from previous work, the main binary for the IPCam runs off a file called “camera”.

As some people have discovered, it likes to reboot the equipment when its not happy (eg when the camera is unplugged, it has issues talking to hardware, or when someone has flashed the wrong firmware).

So, lets take a look at the executable to see what interesting bits we can find out from it.

#file camera tells us – BINFLT file format. Fileflags: RAM GZIP.
So we know its a compressed bflt elf – bflt stands for binary flat file, and it uses gzip compression. It also sits in ram.

A hex dump of camera shows this for the first few bytes:

62 46 4C 54 00 00 00 04 | bFLT . . . .

[Note – I had about 4 pages of #$%# work done on this, and WordPress decided to flake once finished due to an errant pasted 0x0 null byte above, cutting off the rest of my post, so this is going to be shorter and angrier than it was originally written.
Lesson learned, always save stuff elsewhere before posting.

bFLT headers consist of 4 bytes identifier, then 4 bytes for the version number.
In this case, its a version 4 bFLT file.

If we take a look at the header file source for bflt at the uclinux site we see the below layout.

struct flat_hdr {
char magic[4];
unsigned long rev; /* version */
unsigned long entry; /* Offset of first executable instruction with text segment from beginning of file */
unsigned long data_start; /* Offset of data segment from beginning of file */
unsigned long data_end; /* Offset of end of data segment from beginning of file */
unsigned long bss_end; /* Offset of end of bss segment from beginning of file */
/* (It is assumed that data_end through bss_end forms the bss segment.) */
unsigned long stack_size; /* Size of stack, in bytes */
unsigned long reloc_start; /* Offset of relocation records from beginning of file */
unsigned long reloc_count; /* Number of relocation records */
unsigned long flags;
unsigned long filler[6]; /* Reserved, set to zero */

It doesn’t match up properly, as the sizes or code don’t make sense (yet).

If we take a closer look, the header file has this to say:

#define FLAT_FLAG_RAM 0x0001 /* load program entirely into RAM */
#define FLAT_FLAG_GOTPIC 0x0002 /* program is PIC with GOT */
#define FLAT_FLAG_GZIP 0x0004 /* all but the header is compressed */


So, all but the header is compressed for a version 4 file.

Lets check this out, and see if its correct.
Excluding the initial file identifier (bFLT), our header consists of 10 longs. Thats 40 bytes long.
Lets jump to offset 40 in the file, and see what we have there.

1F 8B 08

Those of you familiar with gzipped files will recognize that – its the gzip header identifier. So, so far, so good.
Compressed files aren’t very useful to us, as they don’t show much text content.
So, we could unzip the file to take a look at whats inside.

There are a number of ways we can unzip this (zcat, gzip -d etc), but I’m going to be lazy, and use someone elses premade code.

See below for some perl to safely uncompress our binary , taken from here –



=head1 NAME

gunzip_bflt - convert gzip-compressed bFLT executable files into uncompressed bFLT


gunzip_bflt zipped_blflt_files...


Convert gzipped bFLT files into an uncompressed bFLT files.
The unzipped bFLT files have B<.unz> added to their file names.
If the file is already ungzipped bFLT, it isn't converted,
but a warning is printed.


Uses packages C and C.


use strict;
use warnings;

# gunzip_bflt zipped_blflt_files...

use IO::Uncompress::Gunzip qw/gunzip $GunzipError/;
use POSIX;

# Read and return the BFLT header
# prints a warning and returns undef on error.
# $bfltZfh is the BFLT file handle,
# $bfltZ is the BFLT file name (for error messages)

sub get_bflt_hdr($$) {
my ($bfltZfh, $bfltZ) = @_;
my $buf;
my $res = sysread $bfltZfh, $buf, 64;
if(!defined($res)) {
warn "$bfltZ: $!\n";
return undef;
if($res < 64) { warn "$bfltZ: Too short!\n"; return undef; } # Align the buffered file handle with the unbuffered seek $bfltZfh, sysseek($bfltZfh, 0, SEEK_CUR), SEEK_SET; return $buf; } # Expand a gzipped BFLT intoi an ungziped BFLT sub expand_blftZ($) { my ($bfltZ) = @_; my $bflt = $bfltZ . '.unz'; if(!open BFLTZ, '<' . $bfltZ) { warn "$bfltZ: $!\n"; return; } my $hdr = get_bflt_hdr(\*BFLTZ, $bfltZ); if(!defined $hdr) { return; } if(substr($hdr, 0, 4) eq 'bFLT') { # Pack/unpack template for the BFLT header, 4 bytes ACSII, # 15 little-endian words my $hdrFmt = 'a4 N15'; my @unpHdr = unpack $hdrFmt, $hdr; # Test the header flags 'gzipped' bit if($unpHdr[9] & 4) { # Unset the header flags 'gzipped' bit, and make a new header $unpHdr[9] &= ~4; $hdr = pack $hdrFmt, @unpHdr; if(open BFLT, '>' . $bflt) {

# Write the header
syswrite BFLT, $hdr;

# Align the buffered file handle with the unbuffered
seek BFLT, sysseek(BFLT, 0, SEEK_CUR), SEEK_SET;

# Ungzip from the compressed file into the uncompressed
# file
gunzip \*BFLTZ => \*BFLT
or die "gunzip failed: $GunzipError\n";

close BFLTZ;
} else {
warn "$bflt: $!\n";
} else {
warn "$bfltZ: Not a compressed bFLT file, not gunzipped\n";
} else {
warn "$bfltZ: Not a bFLT file\n";
close BFLT;

# Expand the arguments...

foreach my $bfltZ (@ARGV) {

If we run that on our ‘camera’ executable, we should have an uncompressed bFLT file as output ‘camera.unz’.
Lets run strings on ‘camera.unz’, to see what interesting text content is in there.

Some interesting things of note:

From the variables list below, looks like there is a way to turn off the LED…


We also have a full list of the internal cgi functions now, which might prove useful…

do_cgi: unknown cgi

You can see that Maverick decided to fake the X-Mailer smtp header (Foxmail is a commonly used Mail Program in China).

MIME-Version: 1.0
Content-Type: multipart/mixed;
X-Mailer: Foxmail
Content-Type: image/jpeg;
Content-Transfer-Encoding: base64

I’m interested in why the firmware reboots on some firmwares though, so lets take a deeper look at the code.

To do so, we’ll need to decompile it.
The better equipped than me will probably use something like the nice ARM decompiler plugin for IDA-Pro called Hex-Ray. Unfortunately that costs $$$, and I’m just a hobbyist.

Luckily there is a free windows decompiler called arm2html available here.
arm2html doesn’t handle compressed bFLT files though, so you’ll need to point it at the freshly ungzipped code you got from the perl script above.

As we know that the camera executable reboots after issuing i2c errors, the first piece of decompiled code I wanted to look at was the first piece of code related to i2c:

(excerpted piece below)
02588: e1a0c00d mov ip, sp
00258c: e92dd810 stmdb sp!, {r4, fp, ip, lr, pc}
002590: e24cb004 sub fp, ip, #4 ; 0x4
002594: e24dd00c sub sp, sp, #12 ; 0xc
002598: e59f023c ldr r0, [pc, #572] ; [0027dc] "/dev/i2c0"
00259c: e3a01002 mov r1, #2 ; 0x2
0025a0: eb00c9b8 bl 034c88(c9b8)
0025a4: e1a04000 mov r4, r0
0025a8: e3540000 cmp r4, #0 ; 0x0
0025ac: aa000003 bge 0025c0(3) ; jump
0025b0: e59f0228 ldr r0, [pc, #552] ; [0027e0] "%s: can not open i2c device"
0025b4: e59f1228 ldr r1, [pc, #552] ; [0027e4] "zoom_test"
0025b8: eb00bc86 bl 0317d8(bc86)
0025bc: e91ba810 ldmdb fp, {r4, fp, sp, pc} ; return

The full piece of code essentially loops 7 times trying to open the i2c sensor to call the zoom_test code. If it fails, it calls for a reboot.
Success proceeds to setting up the camera.

We know from our boot log that my camera in this model is a Sonix288.

dvm usb cam driver by Maverick Gao in 2006-8-12
usb.c: registered new driver dvm
dvm usb cam driver 0.1 for sonix288 by Maverick Gao in 2009-4-20
usb.c: registered new driver dvm usb cam driver for sonix288

The Sonix288 is a chipset SoC that will talk to an attached image sensor via i2c. I think that the Sonix288 is probably a standard USB 1.1/2.0 compatible UVC (USB Video Class) chipset from a bit of googling about it.

We don’t have the source for our particular camera though (its secret, much like the data sheets, grrr…).
What to do?
Linux generally uses spcaxxx (and UVC) drivers for talking to camera’s, so lets start taking a look there.

Taking a look at some spcaxxx driver header files and code shows that i2c is setup by first getting the USB VID, USB PID of the hardware, then talking to the i2c device on that hardware.

So, we need to know what our USB VID and PID’s are.

Generally all devices from a given manufacturer will have a single VID as issued by the USB Forum.

If we search through the code for Sonix, it appears that Sonix’s VID is 0x0c45

{USB_DEVICE(0x0c45, 0x607c)}, /* Sonix sn9c102p Hv7131R */
(from )

The Linux UVC page confirms this

(Listings of webcams excerpted – note the VID of 0c45)

0c45:6310 USB 2.0 Camera (Trust Chat Webcam) Sonix Technology
0c45:63e0 Sonix Integrated Webcam (Dell notebooks) Sonix Technology
0c45:63ea Laptop Integrated Webcam 2M (Dell Studio 1555 notebooks) Sonix Technology
0c45:6409 USB 2.0 Camera (Nokia Booklet 3G netbooks) Sonix Technology
0c45:6415 Laptop Integrated Webcam 1.3M (Dell Inspiron 13z notebooks) Sonix Technology

Ideally at this point, I’d have a data sheet for the Sonix288 chip, but the #$%#$ people at Sonix don’t seem to publish one for us mere mortals.

So, we’ll use the next best thing, and use one for their other chipsets.

SN9C1xx PC Camera Controllers –

There is a lot of good useful info in that particular file. We don’t know how much is useful yet, but generally chipsets are quite similar for a given range.

Image sensor / SN9C1xx bridge | SN9C10[12] SN9C103 SN9C105 SN9C120
HV7131D Hynix Semiconductor | Yes No No No
HV7131R Hynix Semiconductor | No Yes Yes Yes
MI-0343 Micron Technology | Yes No No No
MI-0360 Micron Technology | No Yes Yes Yes
OV7630 OmniVision Technologies | Yes Yes Yes Yes
OV7660 OmniVision Technologies | No No Yes Yes
PAS106B PixArt Imaging | Yes No No No
PAS202B PixArt Imaging | Yes Yes No No
TAS5110C1B Taiwan Advanced Sensor | Yes No No No
TAS5110D Taiwan Advanced Sensor | Yes No No No
TAS5130D1B Taiwan Advanced Sensor | Yes No No No

Interesting… Hmm, so it seems that Sonix uses a SN9Cxxx for its product names.
Lets google for SN9C288 instead, and see if we get any results.


From here –

* Sensor: MICRON K14 1,300,000 pixels CMOS
* 5-glass lens,can reach 30 frames/sec. under 640*480
resolutions,software insertion value 1,300,000 pixels
* Focus range: 3CM to infinitude farness
* Dynamic video resolutions: 1280*960 pixels(max.)
* Support microsoft UVC driver-free function
* Support RGB24 and YUY2 two kinds of image formats
* USB 2.0 port,support plug and play
* Human face tracking function

Seems our chipset is finally getting some details.
Max resolution, video modes, face tracking capability, etc
We also know that it can be paired with a Micron K14 image sensor.

Further googling reveals it can also be paired with the MI-0360 (which is listed above).


This page also gives us a possible pid:

“Device Name: ?USB Video Device

PnP Device ID: VID = 0C45 PID = 62C0
Serial Number: 6&&2BCAFCF3&&0&&0000
Revision: (Information not returned)

Device Type: Standard USB device – USB2.0 High-Speed

Chip Vendor: SONiX
Chip Part-Number: SN9C288PFG

In Microsoft parlance, this looks like this USB\VID_0C45&PID_62C0

Googling that gives us a product with windows drivers (HP) and more.

Also says that these product drivers also work.
USB\VID_0C45&PID_62C0 ;SN9C211/213/230

That means we can take a look at their inf file and see if anything useful in there. Unfortunately I did, and there isn’t much 🙁

Sonix has datasheets for some of their other products available though (SN9C2028AF).

First, a quick overview of UVC devices (snarfed from elsewhere).

USB devices are required by the USB specification to respond to the Host device (the computer) with a stream of data describing the device and the interface to the device. This “Device Descriptor” includes vendor, product, and version IDs specific to the manufacturer, the product, and the version of the product. In addition to the device information, the descriptor also includes information on how to talk to the device through a series of “Interface Descriptors”.

The device descriptor for Video is 13.


In addition to the end points described in the interface descriptors, all USB devices support a control pipe to end point 0. This is used to manipulate some of the low level functions of the device such as power, and error status queries.

The USB Video specification describes two interfaces, a control interface to manage the camera, and a stream interface to send or receive video information from the camera.

The control interface is used to manipulate the camera parameters such as brightness and contrast as well as to negotiate a valid set of the video format, frame size, frame rate, and compression rates parameters that describe a video stream. In addition, the control interface can ask the camera for still frame.

In the datasheet for the 2028, it basically states that they use end point 0 for STD Commands, with a maximum packet size of 64 bytes.

Further googling reveals that there is no special driver for it, its a plain UVC 1.0 device.

usb 1-2: New USB device strings: Mfr=2, Product=1, SerialNumber=0
usb 1-2: Product: USB 2.0 Camera
usb 1-2: Manufacturer: Sonix Technology Co., Ltd.
Linux video capture interface: v2.00
uvcvideo: Found UVC 1.00 device USB 2.0 Camera

Further heavy baidu’ing in Chinese sites finds that the SN9C213 and SN9C288 are the same pretty much.


David McCullough very nicely also compiled in usb debug support on his kernel and ran some tests too:

> > > T: Bus=01 Lev=01 Prnt=01 Port=00 Cnt=01 Dev#= 2 Spd=12 MxCh= 0
> > > D: Ver= 2.00 Cls=ef(unk. ) Sub=02 Prot=01 MxPS=64 #Cfgs= 1
> > > P: Vendor=0c45 ProdID=62f1 Rev= 1.00
> > > S: Manufacturer=Sonix Technology Co., Ltd.
> > > S: Product=USB 2.0 Camera
> > > C:* #Ifs= 2 Cfg#= 1 Atr=80 MxPwr=500mA
> > > I: If#= 0 Alt= 0 #EPs= 1 Cls=0e(unk. ) Sub=01 Prot=00 Driver=(none)
> > > E: Ad=83(I) Atr=03(Int.) MxPS= 16 Ivl=6ms
> > > I: If#= 1 Alt= 0 #EPs= 0 Cls=0e(unk. ) Sub=02 Prot=00 Driver=(none)
> > > I: If#= 1 Alt= 1 #EPs= 1 Cls=0e(unk. ) Sub=02 Prot=00 Driver=(none)
> > > E: Ad=81(I) Atr=05(Isoc) MxPS= 128 Ivl=1ms
> > > I: If#= 1 Alt= 2 #EPs= 1 Cls=0e(unk. ) Sub=02 Prot=00 Driver=(none)
> > > E: Ad=81(I) Atr=05(Isoc) MxPS= 256 Ivl=1ms
> > > I: If#= 1 Alt= 3 #EPs= 1 Cls=0e(unk. ) Sub=02 Prot=00 Driver=(none)
> > > E: Ad=81(I) Atr=05(Isoc) MxPS= 512 Ivl=1ms
> > > I: If#= 1 Alt= 4 #EPs= 1 Cls=0e(unk. ) Sub=02 Prot=00 Driver=(none)
> > > E: Ad=81(I) Atr=05(Isoc) MxPS= 600 Ivl=1ms
> > > I: If#= 1 Alt= 5 #EPs= 1 Cls=0e(unk. ) Sub=02 Prot=00 Driver=(none)
> > > E: Ad=81(I) Atr=05(Isoc) MxPS= 800 Ivl=1ms
> > > I: If#= 1 Alt= 6 #EPs= 1 Cls=0e(unk. ) Sub=02 Prot=00 Driver=(none)
> > > E: Ad=81(I) Atr=05(Isoc) MxPS= 956 Ivl=1ms

The uvc driver status is obviously an issue as we’re on a 2.4 Kernel. No uvc support on 2.4.
So…, we either compile 2.6 with UVC support, and reflash, or we continue to use Mavericks driver in lieu of any source.

With that, you have some background on things..
Now, why does this cause a reboot on some machines?

Well, the hardware is different, so the hardware isn’t seen by the driver.
From looking at a few different boards I have seen a few devices id’s used.

So far I have seen these:
vid_0c45/pid_62f1 – (The Sonix Chipset allows you to write pid’s into the device, so this can be changed, or alternately change the driver from 62c0 to 62f1 on these models)

vid_0c45/pid_62c0 – (Our driver is compiled for this)

For those of you with rebooting machines, remove ‘camera &’ from the boot sequence, recompile the kernel with USB verbose debug message logging, and start posting your vid/pid’s here so we can compare, and add to the list.

If someone twisted my arm I could probably oblige…

References: – bFLT file format details. – Common file format headers – bFLT unzip and other tools – IDA Pro and Hex-Ray ARM Decompiler – Arm Decompiler

Files from this post:
(arm2html.exe, bFLT gunzip perl script, original camera bFLT, uncompressed camera bFLT, and camera asm source )
Camera Disassembly, unpacked bFLT and Tools

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I’ve uploaded a zip of my built test image here. I’ve only included telnetd, and ftpd, as the sshd binary is very large, and won’t fit into our rom image space!

If someone is willing to test, feel free.

Test Rom with FTPD and TELNETD binaries added

This rom is 700k+- vs the normal 550kb. So this may / may not overwrite the web ui.

As China’s firewall is being particularly obnoxious this week as to what I can view on the web, I can’t actually get to the info I need to see where they typically write the UI to in rom.

In theory, we should be able to write to the same base address via the boot loader.

The original rom is written here –

Image: 6 name:romfs.img base:0×7F0E0000 size:0×0008D000 exec:0×7F0E0000 -a

And I’m pretty sure that the UI gets written somewhere after this, and not as a separate image. I’d have to run Windows and a sniffer to test this though (using their firmware update software).

Our boot logs show that linux blkmem driver is set to view the whole area from 0×7F0E0000 through to 0x7F16D3FF, so we should easily have 200kb to waste^Hplay with.

From my boot logs:

Blkmem 1 disk images:
0: 7F0E0000-7F16D3FF [VIRTUAL 7F0E0000-7F16D3FF] (RO)

Obstensibly, this should be a matter of going to the bootloader over serial, then uploading our img file.
Suggest rename from testrom.img to romfs.img to be consistent.

It should be something like this:

bootloader > del 6
(delete the current romfs.img)

bootloader > fx 6 romfs.img 0x7f0e0000 0x7f0e0000 -a
Waiting for download
Press Ctrl-x to cancel … (while it waits, you have to select Transfer > Send File in Hyperterminal menu, choose the Xmodem protocol and select my rom image)
Flash programming …

bootloader> boot

Then see what happens in the logs.

It should boot, then attempt to run telnetd and ftpd.
That probably WON’T work just yet, as they’ll complain about missing /etc/ config files.

You might also be missing the UI (as I think this gets written somewhere after our romfs.img in flash)

Send me the serial logs in the comments, and I can fix that up, and repackage.

I also know why the alleged clones (NB they’re not f..king clones sigh, they’re all made by 1 manufacturer here for different people, including FOSCAM) don’t work. The linux.bin for older firmware is set to boot from 0x7f0D0000 as opposed to 0x7f0e0000, so image 6 and 7 both need to be reflashed.

Also of note is that the newer units have gone cheaper, and use 2M flash, previous units had 4M.
uCLinux reports 8M, but its not talking about Flash, just RAM

Be prepared to brick (not completely, as we have a bootloader, and can reflash the original firmware) if it doesn’t work.

If my rom above doesn’t work initially for you, try flashing this before reverting, and see if that helps it boot.


bootloader> del 7

bootloader> fx 7 0x7f020000 0x8000 -acxz
Waiting for download
Press Ctrl-x to cancel ... (while it waits, you have to select Transfer > Send File in Hyperterminal menu, choose the Xmodem protocol and select my
Flash programming ...

bootloader> fx 6 romfs.img 0x7f0e0000 0x7f0e0000 -a
Waiting for download
Press Ctrl-x to cancel ... (while it waits, you have to select Transfer > Send File in Hyperterminal menu, choose the Xmodem protocol and select my rom image)
Flash programming ...

Why aren’t I doing this?

Mostly as I don’t currently have a good serial connection, I’m waiting on headers. Currently I have to hold the serial ports onto the board with fingers, and thats less than reliable!

I should get around to fixing that soonish though, I’m interested in testing this myself…

I’d also appreciate the French contingent adding some info. I’m particularly interested in paillassou’s board photos, and any other firmware people have found for these so I can compare.

I can’t get to Picasa, GadgetVictims, IrishJesus now in China. Grrr.

Yes, I know, use a VPN or proxy… Unfortunately what we do precludes doing so, as I’d probably get told off by our beloved government here, and thats not worth the risk…

Comments please.

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So far in this series, we’ve learnt a few things.
First, is that this hardware is quite nice for hacking purposes, as they’ve left the uBoot in a nice state, and have easily accessible debug ports.
Second is that doing this kind of thing isn’t really that complicated, and can be quite fun.

We’re pretty much ready to start doing our own coding, as we know how the images are packed, and we can use the uBoot to either flash onl the romfs on or own, or alternately roll a complete linux + romfs binary image.

For that, we’ll need to be ready to roll up our sleeves, and actually do some development (finally!).

Getting a development environment setup is our next step, as we’re ready to test out adding binaries.

I’m using Debian, but most Linux environments should be similar. OSX is BSD based, and more of a pain due to Apple not putting everything needed in the normal places, so I’m doing this in a VM on my Macbook under Debian.

Go grab a copy of “NUC700 Series MCU uCLinux” from here

Setup a VM for Debian (not going to cover that) or install Debian or similar.

Copy the zip file to /home in the OS you use.

cd /home
mkdir N745
cd N745
unzip ../NUC700\ Series\ MCU\ uCLinux\

You should now see something like this:

:/home/N745/NUC700 Series MCU uCLinux BSP# ls -al
total 68
drwxr-xr-x 6 root root 4096 2009-05-15 20:02 .
drwxr-xr-x 3 root root 4096 2010-04-30 02:23 ..
drwxr-xr-x 3 root root 4096 2009-05-15 20:06 bootloader
drwxr-xr-x 2 root root 4096 2009-05-15 20:03 bsp
drwxr-xr-x 2 root root 4096 2009-05-15 20:02 doc
drwxr-xr-x 4 root root 4096 2009-05-15 20:02 mkrom
-r--r--r-- 1 root root 44632 2009-03-27 11:49 NUC700 uClinux BSP Release Note.pdf
debian:/home/N745/NUC700 Series MCU uCLinux BSP#

Unfortunately the build *really* doesn’t like long filenames, so lets move all this to the N745 folder, and get rid of the annoyingly named folder.

/home/N745/NUC700 Series MCU uCLinux BSP# mv * ..
/home/N745/# cd ..
/home/N745/# rm -r NUC700\ Series\ MCU\ uCLinux\ BSP/

We still need to unzip the BSP, as its compressed, so go into bsp

/home/N745/# cd bsp
/home/N745/bsp# tar -xzvf NUC700BSP.tar.gz

Yay, yet another bloody subdirectory. Sigh.

/home/N745/bsp# cd NUC700BSP
debian:/home/N745/bsp/NUC700BSP# ls -al
total 183300
drwxr-xr-x 2 shanghaiguide shanghaiguide 4096 2009-03-26 22:38 .
drwxr-xr-x 3 root root 4096 2010-04-30 02:29 ..
-rw-r--r-- 1 shanghaiguide shanghaiguide 29521418 2009-03-26 21:55 applications.tar.gz
-rw-r--r-- 1 shanghaiguide shanghaiguide 43742203 2009-03-26 21:22 arm_tools_3.3.tar.gz
-rw-r--r-- 1 shanghaiguide shanghaiguide 36108739 2009-03-26 21:11 arm_tools.tar.gz
-rw-r--r-- 1 shanghaiguide shanghaiguide 5643452 2009-03-26 21:24 build.tar.gz
-rwxr--r-- 1 shanghaiguide shanghaiguide 4370 2009-03-26 22:31
-rw-r--r-- 1 shanghaiguide shanghaiguide 72439431 2009-03-26 20:53 uClinux-dist.tar.gz

Run the install – I’ve decided to install the whole shebang to /home/N745

Note – The observant amongst you will notice I’m running this as root.
This is NOT recommended. I’m running under a VM solely created to play with this, so I don’t really care if I break it (as I can roll back to the initial install image fairly easy in vmware). Don’t do this yourselves (unless you want to break things).

debian:/home/N745/bsp/NUC700BSP# ./
firstly install arm_tools.tar.gz -->/usr/local/
wait for a while
successfully finished installing arm_tools.tar.gz
now begin to install build.tar.gz,applications.tar.gz and uClinux-dist.tar.gz
Please enter your absolute path for installing build.tar.gz, applications.tar.gz and uClinux-dist.tar.gz:
/home/N745 has existed
please wait for a while, it will take some time
whole installation finished successfully!

We finally have our build environment unzipped, and its sitting in nuc700-uClinux.

debian:/home/N745# cd nuc700-uClinux/
debian:/home/N745/nuc700-uClinux# ls -al
total 24
drwxr-xr-x 6 root root 4096 2010-04-30 02:31 .
drwxr-xr-x 7 root root 4096 2010-04-30 02:31 ..
drwxr-xr-x 7 root root 4096 2009-03-25 00:44 applications
drwxr-xr-x 2 root root 4096 2009-03-26 21:23 image
drwxr-xr-x 12 root root 4096 2009-03-26 04:54 romdisk
drwxr-xr-x 10 root root 4096 2009-03-26 06:50 uClinux-dist

uClinux-dist has the default binaries we want, plus we need to configure the kernel, so lets visit there first (the more adventurous can look at the other folders)

debian:/home/N745/nuc700-uClinux# cd uClinux-dist/
debian:/home/N745/nuc700-uClinux/uClinux-dist# ls -al
total 84
drwxr-xr-x 10 root root 4096 2009-03-26 06:50 .
drwxr-xr-x 6 root root 4096 2010-04-30 02:31 ..
drwxr-xr-x 2 root root 4096 2009-01-22 23:27 bin
drwxr-xr-x 3 root root 4096 2009-03-26 06:50 config
-rw-r--r-- 1 root root 18007 2009-01-22 23:29 COPYING
drwxr-xr-x 3 root root 4096 2009-01-22 23:27 Documentation
drwxr-xr-x 11 root root 4096 2009-01-22 23:29 freeswan
drwxr-xr-x 5 root root 4096 2009-01-22 23:29 lib
drwxr-xr-x 15 root root 4096 2009-03-26 06:50 linux-2.4.x
-rw-r--r-- 1 root root 3228 2009-01-22 23:28 MAINTAINERS
-rw-r--r-- 1 root root 7977 2009-01-22 23:27 Makefile
-rw-r--r-- 1 root root 4935 2009-01-22 23:29 README
-rw-r--r-- 1 root root 1654 2009-01-22 23:29 SOURCE
drwxr-xr-x 158 root root 4096 2009-01-22 23:28 user
drwxr-xr-x 4 root root 4096 2009-03-12 03:54 vendors

Looks like it should be fairly easy, right?

The default build doesn’t work. Why would it be that easy.

You’ll end up with issues like:

entry-armv.S:782: Error: Internal_relocation (type 210) not fixed up
entry-armv.S:784: Error: Internal_relocation (type 208) not fixed up

So, we need to make sure we start off fresh.
Also, note that we’re building for an N745 cpu, so we’ll need to configure that at the make config stage.
Lastly, and EXTREMELY important, is that we’ll need to put our required tools in the path.

sample PATH below:


debian:/home/N745/nuc700-uClinux/uClinux-dist# PATH=/usr/local/sbin:/usr/local/bin:/usr/sbin:/usr/bin:/sbin:/bin:/usr/local/arm_tools/bin

debian:/home/N745/nuc700-uClinux/uClinux-dist#make clean

Now we have a choice - Recommend use make xconfig if possible.
You need to have a GUI, and have tk installed. (apt-get install tk)
Otherwise run make config, and run through the tediously large amount of questions


debian:/home/N745/nuc700-uClinux/uClinux-dist#make xconfig

OPTION#not recommended

debian:/home/N745/nuc700-uClinux/uClinux-dist# make config
config/mkconfig >
# No defaults found
* Target Platform Selection
* Choose a Vendor/Product combination.
Vendor/Product (nuvoton/nuc710, nuvoton/nuc740, nuvoton/nuc745) [nuvoton/nuc710] (NEW) nuvoton/nuc745

[For the rest, I used the defaults (except for the Network Tools questions, which I said Y to all)]

Continue here from whatever menu (x)config you used.

debian:/home/N745/nuc700-uClinux/uClinux-dist#make oldconfig

[Needed, or compile doesn't work]

debian:/home/N745/nuc700-uClinux/uClinux-dist#make dep

[A gazillion pages of info later, we have a build environment!]

We’re finally ready to use our weapon of mass destruction.


It should compile without issue.

Next step is to mount our created rom image, and copy the binaries off, or just go to the compiled folders, and get the binaries.

I’ve done this step already, and have a zip file of a few useful files ready.

-rwxr-xr-x 1 root root 110888 2010-04-30 03:50 ftpd
-rwxr-xr-x 1 root root 55164 2010-04-30 03:52 ping
-rwxr-xr-x 1 root root 1201904 2010-04-30 03:51 ssh
-rwxr-xr-x 1 root root 1219864 2010-04-30 03:51 sshd
-rwxr-xr-x 1 root root 118004 2010-04-30 03:45 telnet
-rwxr-xr-x 1 root root 45460 2010-04-30 03:45 telnetd

file *
ftpd: BFLT executable – version 4 ram
ping: BFLT executable – version 4 ram
ssh: BFLT executable – version 4 ram
sshd: BFLT executable – version 4 ram
telnet: BFLT executable – version 4 ram
telnetd: BFLT executable – version 4 ram

Download that here – arm7-nettools

All we need to do now is mount our romfs image, unzip the, copy the arm7 bFLT binaries over to bin, add telnetd, sshd, and ftpd to our /bin/init, and rebuild by running genromfs on our filesystem.

We can then finally flash our new romfs, and test it out.

Don’t forget that romfs is a read only file system, so we can’t modify it by mounting it. We need to mount, copying everything to elsewhere, do our required bits and pieces, then rebuild.


mount -o loop -t romfs still_unsure.img /mnt/test -r

mkdir /mnt/new
cd /mnt
rsync -arv /mnt/test/ new
cd new/bin

[We need to also edit init]
pico init



eg –
cat init
mount -t proc none /proc
mount -t ramfs none /usr
mount -t ramfs none /swap
mount -t ramfs none /var/run
mount -t ramfs none /etc
mount -t ramfs none /flash
mount -t ramfs none /home

Change to the next directory up, and lets run genromfs

genromfs -d new -f testrom.img
debian:/mnt# ls testrom.img
debian:/mnt# ls -al testrom.img
-rw-r–r– 1 root root 3329024 2010-04-30 04:18 testrom.img

In theory, this should be usable (famous last words!).

Unfortunately, I can’t try testing on that at home, as all the equipment is at the office, but that should be fairly easy.

Probably also some small config issues to sort out, as ftpd, telnetd and sshd will probably choke without their related /etc/whatever config files needed, but we can sort that out via serial on the debug ports.

Flattr this!

I’ve finally received my 2nd camera, so I can now start working properly on it (assuming I get some free time too!)

High resolution photos of the board are below:

Main parts used are:

RAM – Winbond W9812G61H-6 (2M)
According to the data sheet, that 2M X 4 BANKS X 16 BITS SDRAM @ 3.3V / 166MHz/CL3
Data sheet is here –

Flash – Spansion S29AL016D (2M)
Other boards are populated with different providers – some people have Samsung flash…
Mine has the Spansion onboard both units. Its programmable onboard (via the uBoot)
Data sheet here –

Sound Card – ALC203
This is obviously used as the BSP for the Novotel provides sample code for that card, making their life easier…
Data sheet here –

Wired Ethernet – Davicom DM9161AEP (10/100 Ethernet)
Data sheet here –

8 Port Relay Driver (for the motors etc) – ULN2803
Data sheet here –
More info / explanation here –

Wifi – RALINK 2571 (on daughterboard). Wireless G
This is a USB based chipset, so we’re using 4 usb connector pins for this one.
No datasheet, as Ralink are dicks.

CPU – ARM7 N745CDG (Arm 7 by Nuvoton)
Lot of info for chip available at Nuvoton.

W90N745 makes use of the ARM7TDMI microprocessor core of ARMR and 0.18um production to achieve standard operation at 80MHz. 128-Pin LQPF packing is also used to save electricity and lower costs. The built-in 4KBytes I-Cache and 4KBytes D-Cache of W90N745 can also be set as On-Chip RAM according to the needs of product developers. With regards to system integration, W90N745 is suitable for network-related applications such as management switch, IP cameras, VoIP and printer servers.
* One Ethernet MAC
* One USB 2.0 full speed Host controller
* One USB 2.0 full speed Host/Device controller
* AC97/I2S
* 4 UARTs
* I²C Master
* 31 GPIOs
* Power Management

Data sheets –
The uclinux sample distribution and files can be downloaded here –

I’m just waiting on a JLINK USB adaptor, then I’m ready to roll.


David M from comments at provided his rom sizing from his device, I’ve got some notes on that here.

MAC Address : 00:30:10:C1:D0:39
IP Address :
DHCP Client : Enabled
CACHE : Enabled
BL buffer base : 0×00300000
BL buffer size : 0×00100000
Baud Rate : -1
USB Interface : Disabled
Serial Number : 0xFFFFFFFF

For help on the available commands type ‘h’

Press ESC to enter debug mode …

bootloader > ls
Image: 0 name:BOOT INFO base:0x7F010000 size:0×00000038 exec:0x7F010000 -af
Image: 7 name:linux.bin base:0x7F020000 size:0x000BB334 exec:0×00008000 -acxz
Image: 6 name:romfs.img base:0x7F0E0000 size:0x0008D000 exec:0x7F0E0000 -a

My notes:

Image: 0 name:BOOT INFO base:0x7F010000 size:0×00000038 exec:0x7F010000 -af

[Image 0 is 38 bytes (small!).
Boot info is not the bootloader – 38bytes is way too small for that.
It actually stores our bootloader config settings.
eg ip address, cache setting, boot loader buffer address etc.
Our initial settings are below:

MAC Address : 00:30:10:C1:D0:39 (should be changed, this Mac range belongs to Cisco!)
IP Address : (unset)
DHCP Client : Enabled (pulls ip from dhcp..)
CACHE : Enabled (onboard chip cache)
BL buffer base : 0×00300000
BL buffer size : 0×00100000
Baud Rate : -1 (unset / so defaults to 115,200,8,n,1)
USB Interface : Disabled (NC745 has no USB for bootloader)
Serial Number : 0xFFFFFFFF (unset)

-af indicates Active (a) , and is a Filesystem image (f)]

Image: 7 name:linux.bin base:0x7F020000 size:0x000BB334 exec:0×00008000 -acxz
[Image 7 is our OS – Linux 2.4.20 ucLinux Not sure why Maverick didn’t build on 2.6, there is more hardware support. Probably time dependant – 2.6 may not have been available, plus the Nuvoton sample code is also 2.4 based…

-axcz says active (a) executable (x) copied to ram (c) compressed (z) ]

Image: 6 name:romfs.img base:0x7F0E0000 size:0x0008D000 exec:0x7F0E0000 -a

[Our rom image – aka userland stuff. This is where we’ll be putting our own code. Looks like its stuck quite high up in the flash, although doesn’t need to be given size of the Linux rom. We have plenty of room available.

We’ll need to make appropriate changes to Image 6 size on flashing

-a says active partition.]